[0001] Plasma Renin Activity (PRA) measures the capacity of peripheral blood to generate
the peptide angiotensin I (AngI) and is critical in the diagnosis of disorders of
the renin angiotensin aldosterone system (RAAS). In the RAAS, angiotensinogen, constitutively
manufactured by the liver, is hydrolyzed by renin, an enzyme manufactured by the renal
juxtaglomerular apparatus, to form AngI. AngI can then be cleaved by angiotensin converting
enzyme (ACE) to yield Angiotensin II (AngII), a potent vasoconstrictor and mediator
of a number of downstream RAAS effects. Measurement of renin activity is useful in
the differential diagnosis of individuals with hypertension. Renin levels will be
elevated in patients with hypertension due to renal artery stenosis (i.e., renovascular
hypertension). Measurement of renin activity can also be useful in the diagnosis of
primary aldosteronism. Patients with secondary aldosteronism tend to have low renin
levels. Renin activity can also be used to assess the adequacy of steroid substitution
in patients with adrenal insufficiency. Renin activity will be normal in patients
with adequate supplementation and will be elevated when steroid substitution is inadequate.
[0002] Thus, there is a need for improved lab tests to measure plasma renin activity. There
is a need for improved lab tests that are more cost-efficient, thereby allowing more
frequent testing and also provide clinicians testing results sooner.
US2010/219338 discloses methods for measurement of plasma renin activity by HPLC-mass spectrometry.
Summary
[0003] The present invention provides for methods and the use of systems for determining
activity of plasma renin to generate angiotensin I (AngI), which is critical in the
diagnosis of disorders of the renin angiotensin aldosterone system. In certain embodiments,
the invention comprises a method to measure AngI generation by mass spectrometry and/or
liquid chromatography - tandem mass spectrometry (LC-MS/MS). In certain embodiments,
the invention further incorporates a method to confirm the correct specimen type is
EDTA-Plasma.
[0004] In one embodiment the invention comprises a method for determining an amount of AngI
in a sample. The method comprises the steps of incubating the sample under conditions
suitable to allow plasma renin to generate AngI having a sequence NH2-DRVYIHPFHL-COOH
(SEQ ID NO: 1) from angiotensinogen present in the sample; adding a protease; incubating
the sample under conditions to allow the protease to hydrolyze the AngI to generate
a defined AngI cleavage product; ionizing the defined AngI cleavage product to produce
one or more AngI cleavage product ions detectable by mass spectrometry; and detecting
and quantifying the one or more AngI cleavage product ions by mass spectrometry.
[0005] In certain embodiments, the method may include the use of an internal standard. For
example, the method may comprise the step of adding a stable isotope-labeled AngI
peptide (SIL-AngI) to the sample as an internal standard. As discussed in detail below,
the internal standard may be selected from a variety of appropriate standards. In
some embodiments, the SIL-AngI is a peptide NH2-DRV^YIHP^F^HL-COOH (SEQ ID NO: 3),
wherein ^ indicates an amino acid labeled with a heavy isotope. For example, in one
embodiment, V^ is (13C)5H11(15N)O2, having a mass shift of +6; P^ is (13C)5H9(15N)O2,
having a mass shift of +6; and F^ is (13C)9H11(15N)O2, having a mass shift of +6.
It is noted that there are other embodiments, wherein the SIL-AngI is a peptide NH2-DRVYIHPFHL-COOH
(SEQ ID NO: 1) wherein many combinations of amino acids could be labeled with a heavy
isotope, not confined to the internal standard used in example studies herein (SEQ
ID NO: 3).
[0006] The internal standard provides a way to quantify the amount of the AngI peptide and/or
AngI cleavage product at each step. In alternate embodiments, the SIL-AngI peptide
is added before or after plasma renin mediated generation of Angl, but prior to the
step of adding a protease. Thus, in certain embodiments, the amount of AngI cleavage
product is directly proportional to an amount of an SIL-AngI cleavage product generated
by the protease
[0007] The method may also comprise external calibration (i.e., reference) standards which
provide a known amount of AngI for comparison to the sample so as to quantify the
sample AngI. Thus, in certain embodiments, the method may comprise the step(s) of
generating a plurality of calibration standards comprising known amounts of AngI in
a suitable matrix, wherein each of the plurality of the calibration standards comprises
AngI of SEQ ID NO: 1 that goes through the same steps as the sample AngI. In certain
embodiments, the external calibration standard do not go through all of the assay
steps, but are added at the final steps of ionization and mass spectrometry. Thus,
in certain embodiments, the amount of AngI in the sample is quantified by comparing
an amount of AngI in the sample to an amount of AngI in at least one of the plurality
of calibration standards. The calibration standards generally should include a concentration
range that spans the expected range of AngI in the samples. For example, in certain
embodiments, the calibration standards comprise AngI concentration ranging from 0.25
to 100 ng/mL.
[0008] The method comprises generating an AngI derivative for MS/MS measurement. In certain
embodiments, the derivative is generated by incubating the sample AngI with a protease.
In certain embodiments, the protease is a serine protease. For example, in one embodiment,
the protease is trypsin. For example, in certain embodiments, protease cleavage generates
an AngI cleavage product having a sequence NH2-VYIHPFHL-COOH (SEQ ID NO: 2). In certain
embodiments, the protease generates a SIL-AngI cleavage product having a sequence
NH2-V^YIHP^F^HL-COOH (SEQ ID NO: 4).
[0009] In certain embodiments, the AngI derivative (i.e., cleavage product) is generated
by hydrolysis. For example, in certain embodiments that do not form part of the disclosure,
the chemical hydrolysis agent is formic acid, acetic acid, hydrochloric acid, or any
other agent capable of hydrolyzing AngI.
[0010] Where the AngI cleavage product is AngI of SEQ ID NO: 2, the AngI ions are selected
from the group consisting of ions having a mass/charge ratio of 513.3± 2, 269.2 ±
2, 392.7 ± 2, 257.1 ± 2. Similarly, where the SIL-Angl cleavage product is SIL-AngI
of SEQ ID NO: 4, the SIL-AngI ions are selected from the group consisting of ions
having a mass/charge ratio of 524.3 ± 2, 779.5 ± 2, and 269.2 ± 2.
[0011] The method may, in certain embodiments, comprise the step of terminating plasma renin
activity prior to the step of protease digestion. As discussed in more detail below,
a variety of chemical agents and or physical treatments (e.g., heat) may be used to
terminate plasma renin activity. For example, in certain embodiments, methanol is
added to the sample to terminate plasma renin activity. Where an organic solvent (e.g.,
methanol) is added, the method may further comprise the step of evaporating the solvent
(e.g., methanol) and then reconstituting the sample in a buffer prior to the step
of protease digestion.
[0012] The AngI cleavage product (and internal standard) in the sample, and optionally,
also the calibration standards, may be further purified prior to mass spectrometry.
For example, in certain embodiments, the method comprises the step of subjecting the
AngI cleavage product, and the optional SIL-AngI cleavage product, to liquid chromatography
prior to mass spectrometry.
[0013] As discussed in detail herein, a variety of mass spectrometry methods may be used.
In one embodiment, the ionization is positive electrospray ionization with selected
reaction monitoring (SRM).
[0014] A variety of samples may be used. In certain embodiments, the sample is a biological
fluid obtained from a patient. For example, in certain embodiments, the biological
fluid is plasma. In an embodiment, the plasma comprises ethylenediaminetetraacetic
acid (EDTA) as an anticoagulant.
[0015] In certain embodiments, the samples are verified as being plasma samples that contain
EDTA. Thus, the method may include removing an aliquot from the sample and testing
the aliquot for the presence of EDTA prior to the incubation step to generate AngI.
In one embodiment, the testing for the presence of EDTA comprises addition of a colorimetric
agent, o-cresolphthalein complexone, to react with calcium ions in the sample, such
that samples comprising EDTA remain substantially unchanged in color, whereas samples
that do not have EDTA turn color due to reaction of calcium with the colorimetric
agent.
[0016] The method is additionally a method of measuring plasma renin activity (PRA) according
to any of the preceding embodiments, wherein the level of PRA is calculated based
on the amount of AngI in the sample. In an embodiment, the plasma renin activity is
defined by the amount of AngI generated per unit time. For example, in certain embodiments,
the plasma renin activity is expressed as ng/mL/hr. In one embodiment, the plasma
renin activity has an analytically measurable range (AMR) ranging from about 0.167-66.667
ng/mL/hr.
[0017] Embodiments of the assay are both sensitive and highly specific. In certain embodiments,
the lower limit of quantification (LLOQ) of the plasma renin activity is 0.167 ng/mL/hr
and the upper limit of quantification (ULOQ) of the plasma renin activity is 66.667
ng/mL/hr.
[0018] In other embodiments, the invention comprises use of a system for determining a level
of AngI and/or an activity of plasma renin in a sample. The system may comprise various
stations and/or components for performing steps of the method disclosed herein. For
example, the system may comprise a station for incubating the sample under conditions
to generate AngI from angiotensinogen. The system may also optionally comprise a station
for adding a stable isotope-labeled AngI peptide (SIL-AngI) to the sample. In addition,
the system may also optionally comprise a station for termination of plasma renin
mediated generation of AngI. The system may also comprise a station for digesting
the AngI and the optionally added SIL-AngI to generate defined cleavage products of
each of the AngI and the optional SIL-AngI. In certain embodiments, the components
for incubating the sample, adding the internal standard, terminating plasma renin
activity and/or performing the protease digestion may be performed as part of the
same station.
[0019] The system also comprises a station for mass spectrometry. Thus the system comprises
a station for ionizing the AngI and the optional SII,-AngI defined cleavage products
to generate multiply charged gas-phase ions of the defined AngI cleavage product and
the optional defined SIL-AngI cleavage product. The system also comprises a station
for analyzing the multiply charged gas phase ion by mass spectrometry to determine
the presence and/or amount of the defined AngI cleavage product and the optional defined
SIL-AngI cleavage product in the sample, wherein the amount of the defined cleavage
products is indicative of the activity of plasma renin in the sample. The system may
also comprise a station for chromatographically separating the defined cleavage products
using liquid chromatography (e.g., HPLC) prior to mass spectrometry.
[0020] As noted above, the method may comprise the step of validating that the samples are
plasma containing sufficient coagulant. Thus, in certain embodiments, the system may
comprise a station for testing the sample for the presence of EDTA.
Brief Description of the Figures
[0021] The invention may be better understood by reference to the following non-limiting
figures.
Figure 1 is a flow chart of an embodiment of a method of the invention.
Figure 2 is a schematic of an embodiment of a system of the invention.
Detailed Description
[0022] The description is to be read from the perspective of one of ordinary skill in the
art; therefore, information well known to the skilled artisan is not necessarily included.
Abbreviations
[0023] Various abbreviations may be used in the application. In most, if not all, instances,
the meanings of such abbreviations are known to those of skill in the art. These abbreviations
include the following abbreviations, whose meanings are provided. Other abbreviations
are defined herein.
AMR: Analytically Measurable Range
AngI: Angiotensin 1
APCI: atmospheric pressure chemical ionization
ARR: Aldosterone-Renin-Ratio
BSA: bovine serum albumin
CE: capillary electrophoresis
CRR: Clinically Reportable Range
CZE: capillary zone electrophoresis
DESI: desorption electrospray ionization
DMSO: dimethyl sulfoxide
EDTA: Ethylenediaminetetraacetic Acid
ESI: electrospray ionization
FAB: fast-atom bombardment
HPLC: high-performance liquid chromatography
LAESI: laser ablation electrospray ionization
LC: liquid chromatography
LC-MS/MS: liquid chromatography - tandem mass spectrometry
LLOQ: lower limit of quantitation
LSI: laser spray ionization
MALDESI: matrix-assisted laser desorption electrospray ionization
MALDI: matrix-assisted laser desorption ionization
MRM: multiple-reaction monitoring
MS: mass spectrometry
MS/MS: tandem mass spectrometry
m/z: mass to charge
PMSF: phenylmethane sulfonyl fluoride
PRA: Plasma Renin Activity
PRM: parallel-reaction monitoring
QCs: quality controls
Q-TOF: quadrupole time-of-flight
RAAS: Renin Angiotensin Aldosterone System
RIA: radioimmunoassay
SIM: selected ion monitoring
SPH: St. Paul's Hospital
SRM: selected reaction monitoring
Tris: tris(hydroxymethyl)aminomethane
ULOQ: upper limit of quantitation
Definitions
[0024] The following terms, unless otherwise indicated, shall be understood to have the
following meanings:
As used herein, the terms "a," "an," and "the" can refer to one or more unless specifically
noted otherwise.
[0025] Throughout this application, the term "about" is used to indicate that a value includes
the inherent variation of error for the device, the method being employed to determine
the value, or the variation that exists among the study subjects.
[0026] As used herein, the terms "enzyme activity" or "enzymatic activity" refer to a measure
of plasma renin specific activity as compared to a reference standard or a calibration
curve of a reference standard. In some cases, plasma renin activity is compared to
a population of normal individuals called a reference interval. This reference would
include lower and upper 95% confidence interval limits for plasma renin activity in
an ostensible healthy population. The terms can be used in conjunction with the term
"amount" or "level."
[0027] As used herein, the terms "subject," "individual," and "patient" are used interchangeably.
The use of these terms does not imply any kind of relationship to a medical professional,
such as a physician.
[0028] As used herein, the phrase "liquid chromatography" or "LC" is used to refer to a
process for the separation of one or more molecules or analytes in a sample from other
analytes in the sample. LC involves the slowing of one or more analytes of a fluid
solution as the fluid uniformly moves through a column of a finely divided substance.
The slowing results from the distribution of the components of the mixture between
one or more stationary phases and the mobile phase. LC includes, for example, reverse
phase liquid chromatography (RPLC) and high pressure liquid chromatography (HPLC).
In some cases, LC refers to reverse phase LC with a hydrophobic stationary phase in
combination a mobile phase comprised of water and/or water-miscible organic solvents,
such as methanol or acetonitrile. In some case, LC may refer to ion exchange chromatography,
affinity chromatography, normal phase liquid chromatography, or hydrophilic interaction
chromatography.
[0029] As used herein the term "capillary electrophoresis" (CE) refers to a process for
the separation of one or more molecules or analytes in a sample from other analytes
in the sample, based on their ionic mobility in an electrolyte solution while exposed
to an electric field. CE includes, for example, capillary zone electrophoresis (CZE).
[0030] As used herein, the term "separate" or "purify" or the like are not used necessarily
to refer to the removal of all materials other than the analyte of interest from a
sample matrix. Instead, in some embodiments, the terms are used to refer to a procedure
that enriches the amount of one or more analytes of interest relative to one or more
other components present in the sample matrix. In some embodiments, a "separation"
or "purification" may be used to remove or decrease the amount of one or more components
from a sample that could interfere with the detection of the analyte, for example,
by mass spectrometry.
[0031] As used herein, the term "mass spectrometry" or "MS" refers to a technique for the
identification and/or quantitation of molecules in a sample. MS includes ionizing
the molecules in a sample to form charged molecules (ions) in the gas phase; separating
the charged molecules according to their mass-to-charge ratio; and detecting the charged
molecules. MS allows for both the qualitative and quantitative detection of molecules
in a sample. The molecules may be ionized and detected by any suitable means known
to one of skill in the art. The phrase "tandem mass spectrometry" or "MS/MS" is used
herein to refer to a technique for the identification and/or quantitation of molecules
in a sample, wherein multiple selective steps of mass spectrometry occur, either simultaneously
using more than one mass analyzer or sequentially using a single mass analyzer. As
used herein, a "mass spectrometer" is an apparatus that includes a means for ionizing
molecules, selecting molecules and detecting charged molecules.
[0032] As used herein, "electrospray ionization" or "ESI" refers to a technique used in
mass spectrometry to ionize molecules in a sample while avoiding fragmentation of
the molecules. The sample is dispersed by the electrospray into a fine aerosol. The
sample will typically be mixed with a solvent, usually a volatile organic compound
(e.g., methanol or acetonitrile) mixed with water. The aerosol is then transferred
to the mass spectrometer through an orifice, which can be heated to aid further solvent
evaporation from the charged droplets and, ultimately, form gas-phase ions of the
molecules in the sample.
[0033] As used herein, the term "stable isotopically-labeled" or "stable isotope-labeled"
encompasses the process of enriching a molecule with a non-radioactive isotope of
a given atom so as to alter the average mass of said atom within a molecule and thereby
alter the average mass of said molecule. Generally, this is accomplished by replacing
the light isotopes more frequently found in nature and in natural molecules (e.g.,
carbon-12 or nitrogen-14), with the less common heavy isotopes (e.g., carbon-13 or
nitrogen-15).
[0034] As used herein, a "quadrupole analyzer" is a type of mass analyzer used in MS. It
consists of four circular rods (two pairs) that are set highly parallel to each other.
The quadrupole may be in triple quadrupole format as is known in the art. The quadrupole
analyzer is the component of the instrument that can resolve the charged molecules
of the sample based on their mass-to-charge ratio. One of skill in the art would understand
that use of a quadrupole analyzer can lead to increased specificity of results. One
pair of rods is set at a positive electrical potential and the other set of rods is
at a negative potential. To be detected, an ion must pass through the center of a
trajectory path bordered and parallel to the aligned rods. When the quadrupoles are
operated at a given amplitude of direct current and radio frequency voltages, only
ions of a given mass-to-charge ratio will resonate and have a stable trajectory to
pass through the quadrupole and be detected. As used herein, "positive ion mode" refers
to a mode wherein positively charged ions are detected by the mass analyzer, and "negative
ion mode" refers to a mode wherein negatively charged ions are detected by the mass
analyzer. For "selected reaction monitoring" or "SRM," the amplitude of the direct
current and the radio frequency voltages are set to observe only specific masses
[0035] The term "centrifugation" refers to a process that involves the application of the
centripetal force for the sedimentation of heterogeneous mixtures with a centrifuge.
This increases the effective gravitational force on a sample, for example, contained
in a tube, to more rapidly and completely cause the precipitate (pellet) to gather
on the bottom of the tube. The remaining solution is termed "supernatant."
[0036] The terms "substrate" or "enzyme substrate" are used herein to refer to a material
on which an enzyme acts.
[0037] The term "exogenous" or "external" substrate is a substrate originating from outside
the sample. In certain embodiments, the exogenous/external substrate is a "synthetic"
substrate.
[0038] The term "synthetic" is used here to refer to a man-made molecule, for example, produced
in a laboratory or other similar facility. This will encompass both chemical synthesis
as well as recombinant molecular techniques (i.e., expression from a recombinant nucleic
acid construct).
[0039] The term "sequence" can be used to refer to the order of amino acids in a polypeptide,
which can also be described as "primary structure," or to a polypeptide molecule,
such as a polypeptide with a particular order of amino acids.
[0040] As is known in the art, "proteins", "peptides," and "polypeptides" are chains of
amino acids (typically L-amino acids) whose alpha carbons are linked through peptide
bonds formed by a condensation reaction between the carboxyl group of the alpha carbon
of one amino acid and the amino group of the alpha carbon of another amino acid. Typically,
the amino acids making up a protein are numbered in order, starting at the amino terminal
residue and increasing in the direction toward the carboxy terminal residue of the
protein. The term "peptide" is used to denote a less than full-length protein or a
very short protein unless the context indicates otherwise.
[0041] The term "amino acid sequence" can be used to refer to the one letter amino acid
code that defines a sequence of peptides. The amino acid notations used herein for
the twenty genetically encoded L-amino acids are conventional and are as follows:
TABLE 1
| One Letter Abbreviation |
Three Letter Abbreviation |
Amino Acid |
| A |
Ala |
Alanine |
| N |
Asn |
Asparagine |
| R |
Arg |
Arginine |
| D |
Asp |
Aspartic acid |
| C |
Cys |
Cysteine |
| Q |
Gln |
Glutamine |
| E |
Glu |
Glutamic acid |
| G |
Gly |
Glycine |
| H |
His |
Histidine |
| I |
Ile |
Isoleucine |
| L |
Leu |
Leucine |
| K |
Lys |
Lysine |
| M |
Met |
Methionine |
| F |
Phe |
Phenylalanine |
| P |
Pro |
Proline |
| S |
Ser |
Serine |
| T |
Thr |
Threonine |
| W |
Trp |
Tryptophan |
| Y |
Tyr |
Tyrosine |
| V |
Val |
Valine |
[0042] "Sequence identity" or "sequence similarity" in the context of two or more amino
acid sequences, refer to two or more sequences or subsequences that are the same or
have a specified percentage of amino acids that are the same (for example, 60%, 65%,
70%, 75%, 80%, 85%, 90%, 91%, 92%, 93%, 94%, 95%, 96%, 97%, 98%, 99%), or higher identity
over a specified region, when compared and aligned for maximum correspondence over
a comparison window or designated region. Various tools for measuring sequence similarity
are available, such as protein BLAST available from National Center for Biotechnology
Information, U.S. National Library of Medicine, Bethesda, Maryland, USA. For sequence
comparison, typically one sequence acts as a reference sequence, to which test sequences
are compared. When using a sequence comparison algorithm, test and reference sequences
are entered into a computer, subsequence coordinates are designated, if necessary,
and sequence algorithm program parameters are designated. Default program parameters
can be used, or alternative parameters can be designated. The sequence comparison
algorithm then calculates the percent sequence identities for the test sequences relative
to the reference sequence, based on the program parameters.
[0043] As used herein, the term "similar" or "homologue" when referring to amino acid or
nucleotide sequences means a polypeptide having a degree of homology or identity with
the wild-type amino acid sequence. Homology comparisons can be conducted by eye, or
more usually, with the aid of readily available sequence comparison programs. These
commercially available computer programs can calculate percent homology between two
or more sequences (e.g.
Wilbur, W. J. and Lipman, D. J., 1983, Proc. Natl. Acad. Sci. USA, 80:726-730). For example, homologous sequences may be taken to include amino acid sequences
which in alternate embodiments are at least 70% identical, 75% identical, 80% identical,
85% identical, 90% identical, 95% identical, 96% identical, 97% identical, or 98%
identical to each other.
[0044] As used herein, the term at least 90% identical thereto includes sequences that range
from 90 to 99.99% identity to the indicated sequences and includes all ranges in between.
Thus, the term at least 90% identical thereto includes sequences that are 91, 91.5,
92, 92.5, 93, 93.5. 94, 94.5, 95, 95.5, 96, 96.5, 97, 97.5, 98, 98.5, 99, 99.5 percent
identical to the indicated sequence. Similarly the term "at least 70% identical includes
sequences that range from 70 to 99.99% identical, with all ranges in between. The
determination of percent identity is determined using the algorithms described herein.
[0045] The terms "cleavage," "enzyme cleavage" or "enzymatic cleavage" are used herein to
refer to a process or a result of enzymatic hydrolysis of a polypeptide caused by
an enzyme protease (peptidase or proteinase) or chemical hydrolysis to generate a
defined product.
[0046] The term "cleavage site" is used herein to refer to a location of cleavage by a protease
in a polypeptide. The term "cleavage site" encompasses and may be used to denote "specific
cleavage site," meaning a cleavage site in a polypeptide for which a protease is specific.
[0047] The term "cleavage product" or "enzymatic cleavage product" is used herein to refer
to a polypeptide resulting from enzymatic cleavage by a protease. For example, an
AngI cleavage product can be a tryptic peptide generated from AngI as discussed herein.
Methods for Determining the Presence or Amount of Plasma Renin Activity
[0048] The invention may be embodied in a variety of ways. The invention comprises a method
to measure AngI and plasma renin activity by mass spectrometry. In some embodiments
tandem MS/MS is used. In some embodiments, plasma renin activity is measured by LC-MS/MS.
Also described are systems for measuring plasma renin activity.
[0049] For example, and referring to Figure 1, in one embodiment the invention comprises
a method (100) for determining an amount of AngI in a sample. The method comprises
the step (102) of incubating the sample under conditions suitable to allow plasma
renin to generate AngI peptide having the sequence NH2-DRVYIHPFHL-COOH (SEQ ID NO:
1) from angiotensinogen present in the sample. The method also comprises the step
(106) of adding a protease. Also, the method comprises the step (108) of incubating
the sample under conditions to allow the protease to hydrolyze the AngI to generate
a defined AngI cleavage product. The method also comprises the step (110) of ionizing
the defined AngI cleavage product to produce one or more AngI cleavage product ions
detectable by mass spectrometry. The method further includes the step (112) of detecting
and quantifying the one or more AngI cleavage product ions by mass spectrometry. As
discussed in more detail below, the method may additionally include the step (104)
of adding a stable isotope-labeled AngI peptide (SIL-AngI) to the sample as an internal
standard.
[0050] In some embodiments, the amount of plasma renin enzymatic activity in the sample
need not be quantified. In some embodiments, the method can be used to determine the
presence or absence of plasma renin enzymatic activity in a sample. In other embodiments,
the method is used to determine the amount of AngI in a sample. For example, in some
embodiments and/or aspects, the disclosure provides methods for determining an amount
of AngI and/or plasma renin activity in a sample, comprising the steps of incubating
the sample to generate Angl, optionally optimizing the sample chemistry to obviate
protease activity from sample enzymes, optionally adding an internal standard (e.g.,
SII,-AngI), hydrolyzing the AngI and the optional internal standard, optionally terminating
the hydrolysis in the sample being incubated, optionally chromatographically separating
an AngI cleavage product and the internal standard cleavage product from other components
of the sample using liquid chromatography, and ionizing the AngI cleavage product
and the optional internal standard cleavage product to generate multiply charged ions
that are analyzed by mass spectrometry to determine the amount of AngI cleavage product
and the optional AngI internal standard cleavage product in the sample, wherein a
ratio of the determined amounts of the AngI cleavage product and the AngI internal
standard cleavage product is indicative of the amount of activity of plasma renin
in the sample. Also, in certain embodiments, for example, where the sample is serum
or plasma, an aliquot of the sample is tested to be sure that EDTA (an anticoagulant)
is present in an amount sufficient to chelate certain divalent ions (e.g., Ca2+ and
Mg2+).
[0051] The amount of activity in the sample may be determined by comparison to an external
standard curve. For example, the quantity of AngI peptide may be compared to an external
standard curve of calibration standards generated using a suitable matrix having known
concentrations of AngI added. The method is not limited to a specific number of calibration
levels. In some embodiments, only a single point is need to generate the calibration
curve. In some embodiments, the calibrator may added into the sample.
[0052] An exemplary embodiment of the invention is a method for determining activity of
plasma renin in a sample, which may include the steps of incubating the sample to
generate Angl, NH2-DRVYIHPFHL-COOH (SEQ ID NO: 1) from angiotensinogen. Next, a synthetic
stable isotope labeled AngI peptide analogue for AngI NH2-DRV^YIHP^F^HL-COOH (SEQ
ID NO: 3) is optionally added. The use of a stable isotope labeled internal standard
allows for correction due to less than 100% recovery of AngI peptide (or AngI cleavage
product) at any step. In an embodiment, V^ is (13C)5H11(15N)O2, having a mass shift
of +6; P^ is (13C)5H9(15N)O2, having a mass shift of +6; and F^ is (13C)9H11(15N)O2,
having a mass shift of +6. The sample may then be subjected to optional termination
of the reaction using methanol or another organic reagent, evaporation of the solvent
and reconstitution of the AngI and the optional internal standard SIL-AngI in a buffer.
At this point, a protease is added to generate an AngI cleavage product peptide and
a corresponding optional internal standard SIL-AngI cleavage product. In an embodiment,
the protease is a serine protease. In an embodiment, the protease is trypsin. For
example, in an embodiment, trypsin cleavage of AngI generates the peptide NH2-VYIHPFHL-COOH
(SEQ ID NO: 2) and trypsin cleavage of the SIL-AngI generates NH2-V^YIHP^F^HL-COOH
(SEQ ID NO: 4). Next, the method may include optionally, terminating the protease
cleavage step. The method may further include optionally, chromatographically separating
the AngI cleavage product and the optional SII,-AngI cleavage product from other components
in the sample using liquid chromatography; and analyzing the AngI and SIL-AngI cleavage
product(s) by mass spectrometry to determine presence or amount of cleavage product
in the sample. The presence or the amount of the product of the AngI cleavage product
in the sample is indicative of the presence or the amount of AngI in the sample. In
an embodiment, the ratio of SII,-AngI cleavage product to measured AngI cleavage product
is used to correct for loss of AngI at any step. In an embodiment, the method further
comprises generating a plurality of calibration standards comprising known amounts
of AngI in a suitable matrix. In an embodiment, the amount of AngI in the sample is
quantified by comparing the amount of AngI in the sample to the amount of AngI in
at least one of the plurality of calibration standards assayed as the hydrolyzed products.
[0053] In one embodiment, the internal standard is AngI labeled with heavy isotopes as described
above. As is known, other types of internal standard may be employed. For example,
the internal standard may be unlabeled but have a different amino acid sequence, or
other amino acids in the peptide may be labeled. The internal standard, as well as
the calibration standards may be made by chemical synthesis or recombinant methods.
In some embodiments, the calibration standards may have the amino acid sequence shown
in SEQ ID NO: 1 or SEQ ID NO: 2 and the SIL-AngI may have the have amino acid sequence
shown in SEQ ID NO: 3. Additionally and/or alternatively, the internal standard may
include additional sequences containing differently labeled amino acids. In alternate
embodiments, the reference standards have at least 70%, 75%, 80%, 85%, 90%, 95% sequence
similarity to SEQ ID NO: 1 or SEQ ID NO: 2, and the internal standard has at least
70%, 75%, 80%, 85%, 90%, 95% sequence similarity to SEQ ID NO: 3.
[0054] In an embodiment, plasma renin activity is proportional to the amount of AngI product
created during the incubation period. The AngI product is proportional to the AngI
derivative (e.g., a hydrolyzed cleavage product) that is measured by mass spectrometry.
In certain embodiments, the serine protease incubation (to generate the AngI derivative)
may be terminated by acid and/or temperature quenching of the enzyme. Also, in certain
embodiments, the sample containing the AngI cleavage product and the optional SIL-Angl
cleavage product may be analyzed directly using mass spectrometry. In certain embodiments,
the AngI cleavage product and the optional SIL-AngI cleavage product is analyzed by
liquid chromatography (LC) or another purification technique (e.g., capillary electrophoresis)
coupled with tandem mass spectrometry (MS/MS) to measure the AngI product.
[0055] In an embodiment, the internal standard may be added before or after generation of
AngI but prior to termination of the reaction with methanol or temperature. In an
embodiment, the internal standard may be added after the addition of methanol, but
prior to evaporation of the methanol and reconstitution of the sample in a buffer.
In an embodiment, the measured analyte: internal standard ratio is proportional to
the amount of AngI formed and, thereby, directly proportional to the plasma renin
activity.
[0056] The ionization step results in the formation of multiply charged ions. In certain
embodiments, the ionization step includes ionizing the AngI enzymatic cleavage product
and the optional SIL-AngI cleavage product using an ionization technique, such as
electrospray ionization, atmospheric pressure chemical ionization or atmospheric pressure
photoionization.
[0057] The analyzing step allows for characterization and quantification of the multiply
charged ions formed in the ionization step. In certain embodiments, the analyzing
step includes determining the specific activity of plasma renin. In some embodiments,
the analyzing step uses tandem mass spectrometry. Using the substrate of SEQ ID NO:
1 to generate the product of SEQ ID NO: 2, and the substrate of SEQ ID NO: 3 to generate
the product of SEQ ID NO: 4, the analyzing step may, in certain embodiments, use ions
having an m/z selected from the group consisting of 513.3 ± 2, 269.2 ± 2, 392.7 ±
2, 257.1 ± 2.
[0058] The methods according to the embodiments of the present invention may comprise providing
a sample. In this context, the term "providing" is to be construed broadly. The term
is not intended to refer exclusively to a subject who provided a biological sample.
For example, a technician in an off-site clinical laboratory can be said to "provide"
the sample, for example, as the sample is prepared for purification by extraction
and/or chromatography.
[0059] The invention is not limited to any particular means of sample handling. In certain
embodiments, the sample requires EDTA as an anticoagulant. For example, in certain
embodiments, the sample is a plasma sample comprising EDTA. The amount of EDTA in
the sample should be at a level that is sufficient to chelate the divalent ions (e.g.,
Ca2+, Mg2+) present in the sample. For example, in certain embodiments, the amount
of EDTA added to the sample should result in an EDTA concentration of at least 0.5
- 3 mg/mL.
[0060] Thus, in certain embodiments, the method comprises the step of testing an aliquot
of the sample for the presence of EDTA in the sample in an amount suitable to chelate
the divalent ions present in the sample. The test for EDTA may be performed using
a variety of methods. In some embodiments, the test for EDTA may comprise a colorimetric
agent that detects the presence of divalent ions. A plasma sample that contains sufficient
EDTA for chelation of divalent ions will not be able to interact with the colorimetric
agent to produce a colorimetric signal. In an embodiment, the colorimetric agent is
o-cresolphthalein complexone; this reagent reacts with calcium ions to produce a purple
color. Thus, if EDTA is present in the sample in excess of the calcium ions, the sample
will not change color upon addition of the colorimetric agent. If EDTA is not present
in the sample, or is not present in an amount that chelates the free calcium ions,
the sample will turn a purple color. Such samples are generally not suitable for the
assay.
[0061] Termination of the plasma renin mediated generation of Angl, and/or the protease
mediated digestion of AngI and the optional SII,-AngI in the sample being incubated
is not limited to any particular method. In some embodiments, termination is accomplished
by adding a precipitating reagent to the sample after the appropriate incubation period,
in an amount sufficient to terminate the plasma renin enzymatic reaction. A precipitating
reagent can be methanol, acetonitrile, acetone, 2-propanol, ammonium sulfate, trichloroacetic
acid or perchloric acid. In some embodiments, temperature may be used to effectively
terminate the reaction. The sample may be heated so as to inactivate the plasma renin
or the sample may be cooled, potentially frozen, to slow the reaction to an effective
stop. In some embodiments, the reaction may be stopped by adjusting the sample pH
not conducive for plasma renin activity, for example, below about pH 3 or above about
pH 9. In other embodiments, the reaction may be stopped by adding inhibitors of plasma
renin (and/or the serine protease), such as Tekturna or other protease inhibitors.
In some embodiments, it may not be necessary to terminate the enzymatic reaction.
For example, plasma renin enzymatic reaction may be continuously monitored during
the incubation step by repeated sampling over the course of time, rather than measurement
at a single time point.
[0062] Partial purification of the sample may be used to provide a partially purified sample.
Partial purification can be conducted at various stages of the method. For example,
in some embodiments, partial purification can be conducted after incubation of the
sample and termination of plasma renin activity, resulting in a sample comprising
AngI. In some other embodiments, partial purification can be conducted prior to the
incubation step. More than one partial purification step may be used in the methods
according to the embodiments of the present invention. Partial purification is not
limited by the method or the result of the partial purification. In some embodiments,
the concentrations of one or more of the various components in the sample, other than
the component of interest, have been reduced. For example, concentration of the other
components may be reduced relative to the concentration of enzymatic cleavage product
in the partially purified sample. In another example, concentration of the other components
may be reduced relative to the concentration of AngI in the partially purified sample.
[0063] Thus, the term "removing" or "removal" does not necessarily imply the complete removal
of a component. Some amount of the removed component can still be present in the partially
purified sample, although its concentration relative to that of the component of interest
will be lower than in the pre-extraction sample. In some embodiments, the relative
concentration of the removed component to that of enzymatic cleavage product in the
partially purified sample is no more than 90%, or no more than 75%, or no more than
50%, or no more than 33%, or no more than 25%, or no more than 10% or no more than
5%, or no more than 1%, of its relative concentration to enzymatic cleavage product
in the sample prior to the partial purification step. The invention is not limited
to any particular type of removed component. In some embodiments, one or more of the
removed components is a compound that can interfere with the analysis by mass spectrometry
or with liquid chromatography. One example of partial purification method is centrifugation
after the termination of the reaction by addition of an organic solvent. During the
centrifugation, the precipitated components of thus treated sample are removed, while
the supernatant is further purified and/or analyzed.
[0064] In some embodiments of the invention, the partially purified sample can undergo one
or more processing steps before chromatographic separation. For example, in some embodiments,
the partially purified sample is evaporated. Then, the resulting residue is reconstituted
in a solvent system. Any suitable solvent system can be used for reconstituting the
residue. In some embodiments, the solvent system is a solvent system that is compatible
with chromatographic separation. In some embodiments, the solvent system for reconstitution
includes, but is not limited to, water, methanol, or mixtures thereof. In some other
embodiments, the partially purified sample may undergo an enzymatic treatment so as
to modify the enzymatic cleavage product. For example, the cleavage product may be
further hydrolyzed. In some embodiments, the cleavage product may be further hydrolyzed
with other enzymes.
[0065] In some embodiments, the methods include (comprise) a step of chromatographically
separating the AngI and the optional SII,-AngI cleavage product(s) from other components
in the sample, for example, using liquid chromatography. The invention is not limited
to any particular manner of performing liquid chromatography. In general, the chromatographic
separation step includes using at least one liquid chromatography (LC) column. In
some embodiments, multiple LC columns are used, such as two or more, or three or more,
or four or more LC columns. In some such embodiments two, three, four, five, six,
eight or ten LC columns are used. In some such embodiments, two or more of these LC
columns are arranged parallel to each other and are connected inline to the same mass
spectrometer.
[0066] The invention is not limited to any particular types of columns. Any column suitable
for the separation of enzymatic cleavage product can be used. In some embodiments,
one or more analytical columns are used. In some embodiments, the column is a C18
column, but could be comprised of C12, C8, C4, Phenyl-hexyl, amide, amine, or PFP.
[0067] Further, the invention is not limited to any particular mobile phase. Any suitable
mobile phase can be used, as long as the mobile phase is suitable for use with a particular
LC column and for chromatographically separating enzymatic cleavage product in the
LC column. In some embodiments, the mobile phase is comprised of acetonitrile (0 -
100%). Or, the mobile phase may be comprised of methanol (0 - 100%). In some such
embodiments, the mobile phase employs a gradient, such that the relative ratios of
two or more solvents are varied over time. In some embodiments, the mobile phase is
comprised of ion pairing reagents, such as trifluoroacetic acid, formic acid, ammonium,
heptafluorobutyric acid, and/or acetic acid.
[0068] In certain embodiments, two or more LC columns can be used in parallel and connected
inline to the same mass spectrometer, e.g., to improve throughput. In some such embodiments,
a sample (which can be a partially purified sample) is introduced to the two or more
LC columns at different times. In some embodiments, the introduction of the test sample
to the two or more LC columns is staggered, meaning that there is a pre-determined
time interval separating the introduction of sample to two or more LC columns. Appropriate
time intervals can be selected based on various factors, including the elution time,
column chemistries, and the potential need to avoid interference with the analysis
of the enzymatic cleavage product eluted from one or more of the other LC columns.
[0069] In some embodiments of the invention, an LC column can be placed in series with another
column. For example, in some embodiments, suitable guard columns can be employed.
Those of skill in the art are able to select appropriate guard columns for use in
the present methods. In some embodiments, a guard column is placed in parallel with
another LC column. Such series of two or more columns can also be arranged in parallel,
such that there are two or more series of columns operating in parallel, where each
series contains two or more columns. In other embodiments, online extraction columns
may be employed. For example, online solid phase extraction columns may be used to
separate the hydrolyzed AngI and optional SIL-AngI products in some embodiments of
the method.
[0070] In some embodiments of the invention, the AngI and optional SIL-AngI enzymatic cleavage
product may be purified by electrophoresis. For example, in some embodiments, the
enzymatic cleavage product is separated from potentially interfering substances using
capillary electrophoresis.
[0071] In some embodiments, the methods comprise analyzing the purified or separated enzymatic
cleavage product by mass spectrometry to determine the presence or amount of the AngI
and optional SIL-AngI enzymatic cleavage product. In some embodiments, two or more
of the LC columns feed into the same mass spectrometer. In some further embodiments,
three or more of the LC columns feed into the same mass spectrometer. In some embodiments,
the mass spectrometer is part of a combined LC-MS system.
[0072] The invention is not limited to the use of any particular type of mass spectrometer.
Any suitable mass spectrometer can be used. In some embodiments, the method employs
a tandem mass spectrometer. In some such embodiments, analyzing enzymatic cleavage
product can include, ionizing enzymatic cleavage product, analyzing the ionized enzymatic
cleavage product, fragmenting the enzymatic cleavage product ion into two or more
fragment ions, and analyzing the fragment ions.
[0073] The invention is not limited to the use of a mass spectrometer using any particular
ionization methods. The method may utilize ionization techniques suitable to the generation
of multiply charged ions from the enzymatic cleavage product. Suitable ionization
methods include, but are not limited to photoionization, electrospray ionization,
atmospheric pressure chemical ionization, and electron capture ionization. And in
embodiments that employ fragmenting, any suitable fragmentation technique can be used.
Suitable techniques include, but are not limited to collision induced dissociation,
electron capture dissociation, electron transfer dissociation, infrared multiphoton
dissociation, radiative dissociation, electron-detachment dissociation, and surface-induced
dissociation.
[0074] In some embodiments, the tandem mass spectrometer is a Sciex API5500 triple quadrupole
mass spectrometer. In some embodiments, the tandem mass spectrometer has an atmospheric
pressure ionization source, and the analyzing step comprises an ionization method
selected from the group consisting of photoionization, matrix assisted laser desorption/ionization
(MALDI), electrospray ionization (ESI), atmospheric pressure chemical ionization (APCI),
electron capture ionization, electron ionization, fast atom bombardment/liquid secondary
ionization (FAB/LSI), field ionization, field desorption, thermospray/plasmaspray
ionization, particle beam ionization, and so-called "hybrid ionization" techniques,
such as laser ablation electrospray ionization (LAESI), desorption electrospray ionization
(DESI) or matrix assisted laser desorption electrospray ionization (MALDESI). The
ionization method may be in positive ion mode or negative ion mode. The analyzing
step may also include multiple reaction monitoring (MRM, also referred to as selected
reaction monitoring or SRM) or selected ion monitoring (SIM), and the two or more
biomolecules are analyzed simultaneously or sequentially. In some embodiments, the
analyzing step uses a quadrupole analyzer. In some embodiments, the mass spectrometer
is a triple quadrupole mass spectrometer. In some embodiments, the analyzing step
may be performed with product ion scanning on quadrupole-time-of-flight (Q-TOF) or
quadrupole-orbitrap instrument, such as in parallel reaction monitoring (PRM).
[0075] In some embodiments, the method is not limited by any lower-limit of quantification
(LLOQ) and/or upper-limit of quantification (ULOQ). In some embodiments, the LLOQ
of the plasma renin activity is 0.167 ng/mL/hr and the upper limit of quantification
(ULOQ) of the plasma renin activity is 66.667 ng/mL/hr. In some embodiments, the calibration
curve contains the AngI peptide at an LLOQ of 0.25 ng/mL and a ULOQ of 100 ng/mL
Methods of Generating Reports
[0076] The methods of this invention can be utilized in a method for generating a report
for diagnosing a disease or condition associated with reduced activity of plasma renin
in a subject. One example of such a disease or condition is hypertension. Another
example of such a disease or condition is aldosteronism. Such a method may include
the steps of incubating the sample to generate AngI and then optionally adding an
SIL-AngI peptide as an internal standard prior to termination of the reaction and
then generating an AngI peptide cleavage product and the optional SIL-AngI cleavage
product. The method may further include optionally chromatographically separating
the AngI cleavage product and the optional SIL-AngI cleavage product from other components
of the sample using liquid chromatograph ionizing the AngI cleavage product and the
optional SIL-AngI cleavage product to generate multiply charged ions that are analyzed
by mass spectrometry to determine the amount of AngI cleavage product and the optional
SIL-AngI cleavage product in the sample. In an embodiment where the SIL-AngI internal
standard is used, a ratio of the determined amounts of the AngI cleavage product and
the SIL-AngI product is indicative of the amount of activity of plasma renin activity
in the sample. The methods may further comprise generating a report that recites the
amount of activity of plasma renin activity and/or AngI in the sample.
[0077] Based on the information on the amount of activity of plasma renin in the sample,
one could assess whether a subject has an abnormally low amount of such activity.
Such information can be useful for diagnosing one or more diseases or disorders that
may be associated with aberrant levels of plasma renin activity in a subject. The
features and embodiments of all steps except the steps of generating the report are
described immediately above. As noted above, the method can employ more than one column,
e.g., two or more columns in parallel connected inline to the same mass spectrometer.
[0078] In some disclosures a plasma renin activity measurement may be used to determine
the presence and/or amount of a plasma renin inhibitor in the sample. By mixing at
a known ratio a sample with known low activity with a sample with known normal activity,
the activity of the resulting mixed sample may be measured. Based on the known ratio
of the mixture and known activity of the individual samples, one can compare the measured
activity in the mixture to the expected activity in the mixture, whereby a measured
activity lower than the expected activity is indicative of the presence and amount
of inhibitor in the low activity sample.
Systems
[0079] In another aspect, the invention provides for the use of systems for determining
the presence or amount of plasma renin activity in a sample. Such systems include
various embodiments and sub-embodiments analogous to those described above for methods
according to the embodiments of the present invention. These systems include various
stations and/or components. As used herein, the term "station" is broadly defined
and includes any suitable apparatus or collections of apparatuses (e.g., components)
suitable for carrying out the recited method. The stations need not be integrally
connected or situated with respect to each other in any particular way. The invention
includes any suitable arrangements of the stations with respect to each other. For
example, the stations need not even be in the same room. But in some embodiments,
the stations are connected to each other in an integral unit.
[0080] For example, and referring now to Figure 2, a system (200) comprises a station (202)
for incubating the sample under conditions to generate AngI. Optionally, the system
may further comprise a station (204) for adding a stable isotope-labeled peptide SII,-AngI
as an internal standard to the sample. The system may further comprise a station (206)
to add an agent (e.g., a solvent such as methanol) to terminate the activity of plasma
renin. This station may include components to evaporate the solvent and reconstitute
the sample in a protease digestion buffer. The system includes a station (208) for
adding a protease (e.g., trypsin) to generate an AngI cleavage product and an optional
SIL-AngI cleavage product. In some embodiments, at least some of the station for incubating
the sample, adding the internal standard, termination plasma renin activity, and addition
a protease may be combined as a single station (209)
[0081] The system further comprises allowing a station (210) for multiply charging (i.e.,
ionizing) and analyzing the AngI cleavage product and the optional SII,-AngI cleavage
product by mass spectrometry to determine the amount of the AngI cleavage product
and the optional SIL-AngI cleavage product in the sample, wherein the amount of the
AngI cleavage product is indicative of the activity of plasma renin in the sample.
Optionally, the system may also comprise a station (212) for chromatographically separating
the AngI cleavage product and the optional SIL-AngI cleavage product using liquid
chromatography or other separation methods (e.g., capillary electrophoresis). In an
embodiment, the station for liquid chromatography and mass spectrometry may comprise
a single station (213).
[0082] The system further comprises a station or component for data analysis (214). Also,
the system may also include a station for testing the sample for the presence of EDTA
(216). The system, or parts of the system may be controlled by a computer (218).
[0083] The methods and systems according to the embodiments of the present invention possess
various advantages. For example, the method uses a 90 minute incubation to generate
AngI compared to other embodiments which use 3 - 18 hr incubations, providing a faster
method. In another example, the method uses a colorimetric reagent and buffer to differentiate
EDTA-Plasma from other specimen types, thus ensuring the correct sample type is used.
In another example, hydrolysis can be used to alter the selectivity and/or sensitivity
of the method.
[0084] The following Examples have been included to provide guidance to one of ordinary
skill in the art for practicing representative embodiments of the presently disclosed
subject matter.
Examples
Example 1 -Assay Reagents and Procedures
[0085] Plasma Renin Activity (PRA) is determined by LC-MS/MS using external calibration
curves. The assay includes a 1.5 hr bioassay to generate Angiotensin 1, methanol precipitation,
evaporation and reconstitution, and tryptic digestion to produce a proteolytic peptide
specific to AngI. A stable isotope-labeled peptide (SIL-AngI) is added before methanol
precipitation, such that SIL-AngI also undergoes precipitation, evaporation, reconstitution,
and digestion. Following digestion of the signature and internal-standard peptides,
samples are injected onto a SCIEX 5500 Triple Quadrupole LC-MS/MS system for detection
by positive electrospray ionization with selected reaction monitoring (SRM). The amount
of AngI in each sample is back-calculated from the corresponding calibration curve
generated by spiking a surrogate matrix with AngI reference standard material from
0.25 to 100 ng/mL. PRA is defined by the amount of AngI per unit time, expressed as
ng/mL/hr, making the analytically measurable range (AMR) for this assay 0.167 - 66.667
ng/mL/hr.
Specimens
[0086] A recommended sample is 1 mL of plasma dispensed in EDTA. Collection tubes are generally
filled to completion to ensure a proper blood to anticoagulant ratio and mixed immediately
by gentle inversion to ensure adequate mixing. Plasma should be separated from cells
within 4 hours of venipuncture and frozen until tested. As described below, the presence
of sufficient EDTA in a sample may be tested using a colorimetric agent (e.g., o-cresolphthalein
complexone) that upon chelation of calcium ions will turn purple. If the sample contains
sufficient EDTA to complex the calcium ions in the sample, the sample will not change
color. If the sample does not include sufficient EDTA to complex the calcium ions
in the sample, the sample will change color.
Colorimetric Buffer
[0087] Measure 19 mL of 2-amino-2-methyl-1-propanol reagent and add to 75 mL of distilled
or deionized water. Adjust the pH to 10.7 using 3.0-3.4 mL 6N hydrochloric acid. QS
to 125 mL using deionized or distilled water. Store in an amber bottle. Store at room
temperature (15 - 30 °C) for 3 weeks.
Colorimetric Reagent
[0088] Add 15 mL of 6N hydrochloric acid to 12.5 mL deionized or distilled water. Transfer
25 mg o-cresolphthalein complexone to the solution. Rinse the weighing vessel thoroughly
to remove all of the powder using the Colorimetric Buffer already prepared. QS to
250 mL using distilled or deionized water. Store at room temperature (15 - 30 °C)
for up to 1 month.
Liquid Chromatography
[0089] For HPLC, 5% DMSO, 0.1% Formic Acid in water is used as the A mobile phase and 5%
DMSO, 0.1% Formic Acid in acetonitrile is used as the B mobile phase.
Plasma Renin and Protease Digestion
[0090] PMSF (100 mM) is prepared in methanol; PMSF is added to inhibit proteases other than
plasma renin in the initial incubation to generate AngI. Protease digestion, to generate
AngI and SIL-AngI cleavage products, is performed using trypsin (40 µg/mL Trypsin
in 50 mM Acetic Acid) in 300 mM Tris-Cl, pH 8.0; 0.001% (w/v) Zwittergent 3-16.
Preparation of Working Internal Standard Solution (SIL-AngI)
[0091] The cleavable, labeled peptide (SIL-AngI) is assigned by amino acid analysis (e.g.,
100 µg per vial). One vial is reconstituted using 1 mL of Carrier Matrix (1% (w/v)
BSA in 100 mM Tris-Acetate, pH 6) by vortexing for 30 seconds and then incubating
at room temperature for ≥ 15 minutes to produce a 0.1 mg/mL stock solution. The working
internal standard solution is created by combining 0.75 mL of the stock internal standard
solution with 50 mL of carrier matrix in a clean 200 mL volumetric flask. QS to 200
mL using carrier matrix. Cover, mix well, immediately aliquot for storage. Store at
room temperature for up to 2 hours and discard any residual after use.
Sequence: NH2-DRV^YIHP^F^HL-COOH (SEQ ID NO:3)
Label: V^ = (13C)5H11(15N)O2 [Mass Shift +6]
P^ = (13C)5H9(15N)O2 [Mass Shift +6]
F^ = (13C)9H11(15N)O2 [Mass Shift +6]
Assay Procedure
[0092]
- 1. Thaw samples and calibrators using a circulating water bath at 25 °C. Trypsin solution
should be thawed just before initiating step 3, such that when it is used in step
13 is within 1 hour of removal from the freezer.
- 2. Pre-heat water bath to 37 °C for subsequent steps.
- 3. Pipette 200 µL of blanks, standards, controls, and samples to a 2-mL, 96 deep well
plate, Plate A. Then, pipette 20 µL of blanks, standards, controls, and samples to
96-well microtiter plate (Plate C) for colorimetric screening.
- 4. Pipette 100 µL of 100 mM PMSF in MeOH to 10 mL of Generation Buffer (275 mM Maleic
Acid, pH 1.8). Vortex 5 seconds and immediately transfer 20 µL of Generation Buffer
to each well of Plate A using a 12-channel pipette.
- 5. Centrifuge Plate A briefly, seal using a Microtiter Plate Sealer, vortex for 30
seconds at 1500 rpm, and incubate in the water bath at 37 °C for 1.5 hr.
- 6. Transfer 50 µL of colorimetric buffer and reagent to Plate C. Samples that appear
purple are to be marked on the coversheet as NOT EDTA-Plasma.
- 7. After generation, centrifuge Plate A briefly, then add 50 µL of working internal
standard solution (300 ng/mL SIL-AngI in Carrier Matrix) to each well except for the
double blank, which receives 50 µL of Carrier Matrix.
- 8. Centrifuge Plate A for 10 seconds at 3500 rpm, seal using a Microtiter Plate Sealer,
and vortex for 1 min at 25 °C and 1500 rpm using a ThermoMixer.
- 9. Add 600 µL of methanol to each well of Plate A, seal the plate using a foil seal
and vortex 5 min at 1500 rpm.
- 10. Centrifuge Plate A for 10 min at 3500 rpm.
- 11. Transfer 200 µL of supernatant from Plate A to a new 2-mL, 96 deep-well plate
(Plate B).
- 12. Evaporate the contents of Plate B to dryness using a TurboVap (Flow: 40Fh, Temp:
50 °C)
- 13. Pipette 150 µL of Digestion Buffer into Plate B.
- 14. Pipette 50 µL of Trypsin Solution to each well of Plate B and centrifuge the plate
for 10 seconds at 3500 rpm.
- 15. Seal Plate B using a Microtiter Plate Sealer, incubate for 30 minutes at 25 °C
and 1500 rpm on the ThermoMixer.
- 16. Pipette 20 µL of Quench Solution to each well of Plate B.
- 17. Vortex Plate B for 5 min @ 1500 rpm and centrifuge for 10 seconds at 3500 rpm.
Precursor/Fragment Ions
[0093] For the AngI cleavage peptide (SEQ ID NO: 2) (AngIdesDR) the transitions are selected
from the group consisting of: 650.3 ± 2, 763.4 ± 2, 513.3 ± 2, 269.2 ± 2, 392.7 ±
2, 257.1 ± 2 For the SIL-AngI cleavage peptide (SEQ ID NO: 4) (IS) the transitions
are selected from the group consisting of: 524.3 ± 2, 779.5 ± 2, and 269.2 ± 2.
Example 2 - Validation of the Assay
[0094] The LC-MS/MS method to measure PRA for validation of quantitative methods intended
for use in clinical diagnostic testing and routine clinical trials was validated as
summarized below. The validation included evaluations of matrix effects, sensitivity,
selectivity, stability, inaccuracy, imprecision, linearity, inter-assay comparisons,
reference-interval verification, and automation.
[0095] Specificity of the assay in calibrator matrix (Carrier Matrix: 1% (v/v) BSA, 100
mM Tris-Acetate, pH 6.0) was assessed by evaluating the interference among the matrices
for AngI and SIL-AngI using both (6- and 8-point) calibration series. No interference
was observed in calibrator matrix (
Carrier Matrix: 1% (w/v) BSA, 100 mM Tris-Acetate, pH 6.0, Table 2, 81) and the assay specificity
for AngI is unaffected by SIL-AngI. Further, carryover following the ULOQ is less
than that observed in the LLOQ. These results indicate the assay is specific for the
analysis of AngI in calibrator matrix.
[0096] Given the specificity of the assay, the accuracy and precision of the calibrators
and quality controls was evaluated across intra-assay (20 × 1) and inter-assay (6
× 3, 5 x 5 or 1 × 20) studies. The results indicated the assay is accurate and precise
for the detection of AngI and PRA . For example, recovery at the LLOQ was ≤± 20% bias
and ≤20% CV to the nominal concentration and recovery at the ULOQ was ≤± 15% bias
and ≤15% CV across all studies. Calibrator reproducibility was shown across 5 separate
analytical runs. The relative accuracy of the assay in carrier matrix and EDTA-Plasma
was evaluated by performing mixing and spike and recovery studies. Accurate AngI measurements
after mixing of a high-level calibrator and EDTA-plasma at 3:1, 1:1, and 1:3 ratios
indicated matrix equivalency of 100 ± 5%. Spike and recovery demonstrates the assay
recovers AngI at 5, 10, and 50X the LLOQ in three generated EDTA-plasma specimens
(Table 11). These results indicate that the assay is accurate in carrier matrix and
EDTA-plasma.
[0097] The specificity and accuracy of the assay was interrogated in the presence of interferents.
Only 20 mg/dL conjugated bilirubin affects the analytical measurement of Angl, whereas
10 mg/dL conjugated bilirubin does not, nor does 20 mg/dL un-conjugated bilirubin,
3000 mg/dL triglycerides, 500 mg/dL hemoglobin, or 12 mg/dL total protein. Additionally,
gross hemolysis, icterus, or lipemia did not affect the accuracy of the PRA assay
as demonstrated by sample mixing with a normal EDTA-plasma specimen prior to generation;
however, matched draws of normal and hemolyzed specimens demonstrated some systematic
bias of PRA measurements. This inconsistency is perhaps due to the difference in the
degree of hemolysis between experiments as well as the use of exogenous hemolysate
in the former experiment, which may not contain other cellular components that are
released from red blood cells in a patient-dependent manner that could interfere with
PRA measurements. Thus, the assay is accurate in the presence of interferents, except
for conjugated bilirubin levels at or above 20 mg/dL and moderate-to-gross hemolysis,
which may be rejected.
[0098] Assay accuracy was evaluated for samples are diluted before generation (encompassing
the biology) or after extraction (including only the analytical measurement). Results
demonstrated that it is preferable that specimens are not be diluted before generation
using carrier matrix, but may be diluted after extraction using digestion buffer up
to 50-fold. These studies indicate that patients yielding PRA values above the ULOQ
(66.667 ng/mL/hr) can be diluted into range after extraction using digestion buffer.
[0099] PRA assays often split specimens into two samples for the generation reaction: hot
(37°C) and cold (4°C). In this format, the final PRA measurement consists of subtracting
the AngI measurement in the cold sample from the AngI measurement in the hot sample
to produce an adjusted AngI measurement that accounts for the endogenous basal AngI
in the PRA calculation. To evaluate if the cold sample is required for clinical interpretation
of PRA, the hot and adjusted measurements of 106 patients were compared. Passing-Bablok
regression yields a slope of 1.000 and a correlation coefficient of 0.998, with a
mean bias of 2.032%. These results indicated that only the hot sample is required
for the accurate measurement of PRA.
[0100] The stability of samples and trypsin was evaluated. First, calibrator, quality control,
and specimen stability was interrogated at room temperature, refrigerated, frozen,
and through freeze-thaw cycles. The calibrators are stable through two freeze-thaw
cycles, and for 14 days at RT, refrigerated, frozen (-20 °C), and 128 days frozen
(<-70 °C). The QCs are also stable through two freeze-thaw cycles, but, in contrast
to the calibrators, are stable for 4 hours at RT. Similarly to the calibrators, though,
the QCs are stable for 14 days refrigerated or frozen. Also, the quality controls
are stable for 35 days at <-70 °C. EDTA-Plasma is stable through three freeze-thaw
cycles. In comparison to the QCs, EDTA-Plasma is also stable for four hours at room
temperature after thawing, yet in contrast to both the QCs and Calibrators is unstable
refrigerated. EDTA-Plasma is stable for 14 days frozen (-20 °C). Finally, the stability
of working trypsin solution (40 µg/mL in 50 mM Acetic Acid) and stock trypsin solution
(32 mg/mL in 50 mM Acetic Acid) was evaluated and observed to be stable frozen for
63 days (<-10 °C) and 244 days (<-70 °C), respectively.
[0101] Given the instability of EDTA-Plasma at room temperature, a time-to-freeze stability
study of four patients was performed to provide guidance to collection sites for sample
handling. Briefly, samples were processed immediately (baseline) or incubated at room
temperature (15 - 30°C) for 1, 2, or 4 hours prior to freezing. The results indicate
EDTA-Plasma is stable when processed and frozen within 4 hours after collection from
the patient. Thus, sites of collection should process and freeze EDTA-Plasma samples
from patients after collection with minimal interruption.
[0102] In-process and post-extraction stability of calibrators, controls, and samples was
conducted. Acceptable in-process stability was observed post-generation (on wet ice,
1 hour), post-precipitation (<-10 °C, 55 days), and post-digestion (on wet ice, 1
hour). Additionally, acceptable post-extraction stability was observed on the bench-top
(15-30 °C) for 4 hours and in the autosampler (10 °C) for 10 days.
[0103] To evaluate the harmony among PRA assays, the LC-MS/MS assay was compared to the
protocols of Endocrine Sciences (RIA), Center for Esoteric Testing (RIA, Tables 57,
58), and St. Paul's Hospital (SPH, LC-MS/MS) (
G. Van Der Gugten and D. Holmes, "Quantitation of Plasma Renin Activity in Plasma
Using Liquid Chromatography Tandem Mass Spectrometry (LC-MS/MS)," Clinical Applications
of Mass Spectrometry in Biomolecular Analysis, 2016, 1378:243-253). The LC-MS/MS assay correlated worst to Endocrine Sciences (Slope: 1.123, Mean Bias:
19.6%) and best to SPH (Slope: 1.030, Mean Bias: 1.64%). To verify the SPH reference
interval, 142 reference interval specimens were filtered according to Aldosterone,
serum Sodium, serum Potassium, History, and blood pressure measurements. Verification
of the SPH reference failed (Table 61), due to >10% of samples being below the SPH
lower RI limit.
[0104] Consequently,
de novo reference interval generation was performed. First, 142 specimens were interrogated
for normal Aldosterone [0-30 ng/dL], Sodium [3.5-5.2 mmol/L], Potassium [134-144 mmol/L]
and history of hypertension. EP Evaluator was used to generate a transformed parametric
reference interval of 0.167 ng/mL/hr (fixed at the assay LLOQ) to 5.3804 ng/mL/hr
(4.6091 - 6.2448, 90% CI) and a confidence ratio of 0.16. Given that the PRA assay
is evaluated in the context of the Aldosterone-to-Renin Ratio (ARR), the ARR reference
interval (ng/dL : ng/mL/hr) was also verified using the 142 filtered specimens. The
analytical correlation of the LC-MS/MS aldosterone and PRA assays between the assay
described herein and SPH suggests that patient samples interrogated for the ARR at
either site would receive similar care.
[0105] Agreement between the manual and automated assays was interrogated. Briefly, one
manual plate containing QCs and Patient samples was evaluated against two automated
plates. Passing-Bablok regression of manual v. automated plate 1 yields a 0.919 slope
(0.898 - 0.938 90% CI), an intercept of -0.0108 (-0.0744 - 0.0596; 90% CI) with a
correlation coefficient of 0.9946. Passing-Bablok regression of the manual v. automated
plate 2 yields a 0.948 slope (0.926 - 0.972 90% CI), an intercept of -0.0406 (-0.1058
- 0.0104 90% CI) and a correlation coefficient of 0.9921. These data indicate that
automation can be used for double-plate batches of this PRA assay.
1. Verfahren zum Bestimmen einer Menge von Angiotensin I (Angl) in einer Probe, wobei
das Verfahren umfasst:
(a) Inkubieren der Probe unter Bedingungen, die dazu geeignet sind, Plasma-Renin zu
ermöglichen, Angl mit einer Sequenz NH2-DRVYIHPFHL-COOH (SEQ ID Nr. 1) aus Angiotensin,
das in der Probe vorhanden ist, zu erzeugen;
(b) Zugeben einer Protease;
(c) Inkubieren der Probe unter Bedingungen, um der Protease zu ermöglichen, das Angl
zu hydrolysieren, um ein definiertes Angl-Spaltungsprodukt zu erzeugen;
(d) Ionisieren des definierten Angl-Spaltungsprodukts, um ein oder mehrere Angl-Spaltungsprodukt-Ionen
zu produzieren, die durch Massenspektrometrie nachweisbar sind; und
(e) Nachweisen und Quantifizieren des einen oder der mehreren Angl-Spaltungsprodukt-Ionen
durch Massenspektrometrie.
2. Verfahren nach Anspruch 1, weiterhin umfassend ein Zugeben eines stabilen isotopmarkierten
Angl-Peptids (SIL-Angl) zu der Probe als ein interner Standard.
3. Verfahren nach Anspruch 2, wobei das SIL-Angl ein Peptid NH2-DRV^YIHP^F^HL-COOH (SEQ
ID Nr. 3) ist, wobei ^ eine Aminosäure angibt, die mit einem schweren Isotop markiert
ist, und optional wobei V^ (13C)5H11(15N)O2 mit einer Massenverschiebung von +6 ist;
P^ (13C)5H9(15N)O2 mit einer Massenverschiebung von +6 ist und F^ (13C)9H11(15N)O2
mit einer Massenverschiebung von +6 ist; oder wobei das SIL-Angl aus dem Peptid NH2-DRVYIHPFHL-COOH
(SEQ ID Nr. 1) unter Verwendung anderer Kombinationen von Aminosäuren, die mit einem
schweren Isotop markiert sind, erzeugt ist; oder wobei das SIL-Angl-Peptid vor oder
nach einer Plasma-Renin-vermittelten Erzeugung von Angl, jedoch vor dem Schritt des
Zugebens einer Protease zugegeben wird; oder wobei die Menge von Angl-Spaltungsprodukt
direkt proportional zu einer Menge eines SIL-Angl-Spaltungsprodukts, das durch die
Protease erzeugt wird, ist.
4. Verfahren nach einem der Ansprüche 1 bis 3, weiterhin umfassend ein Erzeugen von mehreren
Kalibrationsstandards, umfassend bekannte Mengen von Angl in einer geeigneten Matrix,
wobei jeder der mehreren Kalibrationsstandards Angl der SEQ ID Nr. 1 umfasst, das
dieselben Schritte wie das Proben-Angl durchläuft; und optional wobei die Menge von
Angl in der Probe durch Vergleichen einer Menge von Angl in der Probe mit einer Menge
von Angl in mindestens einem von den mehreren Kalibrationsstandards quantifiziert
wird; und optional wobei die Kalibrationsstandards eine Angl-Konzentration umfassen,
die von 0,25 bis 100 ng/mL reicht.
5. Verfahren nach einem der Ansprüche 1 bis 4, wobei die Protease eine Serinprotease
und optional Trypsin ist.
6. Verfahren nach einem der Ansprüche 1 bis 4, wobei eine Proteasespaltung ein Angl-Spaltungsprodukt
mit einer Sequenz NH2-VYIHPFHL-COOH (SEQ ID Nr. 2) erzeugt.
7. Verfahren nach einem von Anspruch 3 und den Ansprüchen 4 bis 6 bei Abhängigkeit von
Anspruch 3, wobei die Protease ein SIL-Angl-Spaltungsprodukt mit einer Sequenz NH2-V^YIHP^F^HL-COOH
(SEQ ID Nr. 4) erzeugt.
8. Verfahren nach einem der Ansprüche 1 bis 7, wobei die AngI-Ionen aus der Gruppe bestehend
aus Ionen mit einem Masse-/Ladungsverhältnis von 513,3 ± 2, 269,2 ± 2, 392,7 ± 2,
257,1 ± 2 ausgewählt sind.
9. Verfahren nach einem von Anspruch 2 und den Ansprüchen 3 bis 8 bei Abhängigkeit von
Anspruch 2, wobei die SIL-Angl-Ionen aus der Gruppe bestehend aus Ionen mit einem
Masse-/Ladungsverhältnis von 524,3 ± 2, 779,5 ± 2 und 269,2 ± 2 ausgewählt sind.
10. Verfahren nach einem der Ansprüche 1 bis 9, weiterhin umfassend ein Beenden der Plasma-Renin-Aktivität
vor dem Schritt eines Proteaseverdaus; und optional wobei Methanol der Probe zugegeben
wird, um die Plasma-Renin-Aktivität zu beenden; und optional weiterhin umfassend ein
Verdampfen des Methanols und dann ein Rekonstituieren der Probe in einem Puffer vor
dem Schritt des Proteaseverdaus.
11. Verfahren nach einem der Ansprüche 1 bis 10, wobei das Angl-Spaltungsprodukt und das
optionale SIL-Angl-Spaltungsprodukt einer Flüssigkeitschromatographie vor der Massenspektrometrie
unterzogen werden; und/oder wobei die Ionisation eine positive Elektrospray-Ionisation
mit Selected Reaction Monitoring (SRM) ist.
12. Verfahren nach einem der Ansprüche 1 bis 11, wobei die Probe ein biologisches Fluid
ist, das von einem Patienten erhalten wird; und optional wobei das biologische Fluid
Plasma ist; und optional wobei das biologische Fluid Ethylendiamintetraessigsäure
(EDTA) als ein Antikoagulans umfasst.
13. Verfahren nach einem der Ansprüche 1 bis 12, weiterhin umfassend vor dem Inkubationsschritt
zum Erzeugen von Angl ein Entnehmen eines Aliquots aus der Probe und ein Testen des
Aliquots auf das Vorhandensein von EDTA; und optional wobei das Testen auf das Vorhandensein
von EDTA eine Zugabe eines kolorimetrischen Mittels, o-Kresolphthalein-Komplexon,
umfasst, um mit Calcium-Ionen in der Probe zu reagieren, so dass die Farbe von Proben,
die EDTA umfassen, im Wesentlichen unverändert bleibt, wohingegen die Farbe von Proben,
die kein EDTA aufweisen, aufgrund einer Reaktion von Calcium mit dem kolorimetrischen
Mittel umschlägt.
14. Verfahren nach einem der vorhergehenden Ansprüche, wobei weiterhin das Niveau der
Plasma-Renin-Aktivität auf der Basis der Menge von Angl in der Probe berechnet wird;
und optional wobei die Plasma-Renin-Aktivität durch die Menge von Angl, die pro Zeiteinheit
erzeugt wird, definiert wird oder wobei die Plasma-Renin-Aktivität als ng/mL/h ausgedrückt
wird und/oder wobei die Plasma-Renin-Aktivität einen analytisch messbaren Bereich
(AMR) aufweist, der von 0,167-66,667 ng/mL/h reicht, und/oder wobei die untere Quantifizierungsgrenze
(LLOQ) der Plasma-Renin-Aktivität 0,167 ng/mL/h beträgt und die obere Quantifizierungsgrenze
(ULOQ) der Plasma-Renin-Aktivität 66,667 ng/mL/h beträgt.
15. Verwendung eines Systems zur Bestimmung eines Spiegels von Angl und/oder einer Aktivität
von Plasma-Renin in einer Probe in dem Verfahren nach einem der Ansprüche 1 bis 14,
wobei das System umfasst:
(a) eine Station zum Inkubieren der Probe unter Bedingungen, um Angl aus Angiotensin
zu erzeugen;
(b) optional eine Station zum Zugeben eines stabilen isotopmarkierten Angl-Peptids
(SIL-Angl) zu der Probe;
(c) optional eine Station zum Beenden einer Plasma-Renin-vermittelten Erzeugung von
Angl;
(d) eine Station zum Verdauen des AngI und des optional zugegebenen SIL-Angl, um definierte
Spaltungsprodukte von jeweils dem Angl und dem optionalen SIL-Angl zu erzeugen;
(e) eine Station zum Ionisieren des definierten Angl- und des optionalen definierten
SIL-Angl-Spaltungsprodukts, um mehrfach geladene Gasphasenionen des definierten Angl-Spaltungsprodukts
und des optionalen definierten SIL-Angl-Spaltungsprodukts zu erzeugen; und
(f) eine Station zum Analysieren des mehrfach geladenen Gasphasenions durch Massenspektrometrie,
um das Vorhandensein und/oder die Menge des definierten Angl-Spaltungsprodukts und
des optionalen definierten SIL-Angl-Spaltungsprodukts in der Probe zu bestimmen, wobei
die Menge der definierten Spaltungsprodukte die Aktivität von Plasma-Renin in der
Probe angibt; und optional weiterhin umfassend eine Station zum Testen der Probe auf
das Vorhandensein von EDTA; und/oder weiterhin umfassend eine Station zum chromatographischen
Trennen der definierten Spaltungsprodukte unter Verwendung von Flüssigkeitschromatographie.
1. Procédé pour déterminer un montant d'angiotensine I (AngI) dans un échantillon, le
procédé consistant à :
(a) incuber l'échantillon sous des conditions appropriées permettant à de la rénine
plasmatique de générer de l'Angl ayant une séquence NH2-DRVYIHPFHL-COOH (SEQ ID N°
1) à partir de l'angiotensinogène présent dans l'échantillon ;
(b) ajouter une protéase ,
(c) incuber l'échantillon sous des conditions permettant à la protéase d'hydrolyser
l'Angl pour générer un produit de clivage de l'Angl défini ;
(d) ioniser le produit de clivage de l'Angl défini pour produire un ou plusieurs ions
produits de clivage de l'Angl détectables par spectromètre de masse ; et
(e) détecter et quantifier le ou plusieurs ions produits de clivage de l'Angl par
spectromètre de masse.
2. Procédé selon la revendication 1, consistant en outre à ajouter un peptide Angl marqué
par isotope stable (SIL-Angl) à l'échantillon comme étalon interne.
3. Procédé selon la revendication 2, dans lequel le SIL-Angl est un peptide NH2-DRVAYIHPAFAHL-COOH
(SEQ ID N° 3), dans lequel A indique un acide aminé marqué par un isotope lourd, et
éventuellement dans lequel VA représente (13C)5H11(15N)O2, affichant un décalage de
masse de +6 , PA représente (13C)5H9(15N)O2, affichant un décalage de masse de +6
; et FA représente 13C)9H11(15N)O2, affichant un décalage de masse de +6 ; ou dans
lequel le SIL-Angl est généré à partir du peptide NH2-DRVYIHPFHL-COOH (SEQ ID N° 1)
en utilisant d'autres combinaisons d'acides aminés marqués par un isotope lourd ;
ou dans lequel le peptide SIL-Angl est ajouté en amont ou en aval de la génération
d'Angl médiée par rénine plasmatique, mais en amont de l'étape consistant à ajouter
une protéase ; ou dans lequel le montant de produit de clivage de l'Angl est directement
proportionnel à un montant d'un produit de clivage du SIL-Angl généré par la protéase.
4. Procédé selon l'une quelconque des revendications 1 à 3, consistant en outre à générer
une pluralité d'étalons de calibrage comportant des montants connus d'Angl dans une
matrice appropriée, dans lequel chaque étalon de calibrage de la pluralité des étalons
de calibrage comporte une Angl ayant une SEQ ID N° 1 qui passe par les mêmes étapes
que celles de l'Angl de l'échantillon ; et éventuellement dans lequel le montant d'Angl
que contient l'échantillon est quantifié en le comparant à un montant d'Angl que contient
l'échantillon à un montant d'Angl dans au moins un étalon de calibrage de la pluralité
d'étalons de calibrage ; et éventuellement dans lequel les étalons de calibrage comprennent
une concentration d'Angl allant de 0,25 à 100 ng/mL.
5. Procédé selon l'une quelconque des revendications 1 à 4, dans lequel la protéase est
une sérine-protéase ; et éventuellement de la trypsine.
6. Procédés selon l'une quelconque des revendications 1 à 4, dans lequel le clivage de
protéase génère un produit de clivage d'Angl ayant une séquence NH2-VYIHPFHL-COOH
(SEQ ID N° 2).
7. Procédé selon l'une quelconque de la revendication 3 et des revendications 4 à 6 lorsque
relevant de la revendication 3, dans lequel la protéase génère un produit de clivage
de SIL-Angl ayant une séquence NH2- VAYIHPAFAHL-COOH (SEQ ID N° 4).
8. Procédé selon l'une quelconque des revendications 1 à 7, dans lequel les ions de l'Angl
sont sélectionnés dans le groupe consistant d'ions ayant un rapport masse sur charge
de of 513,3± 2, 269.2 ± 2. 392,7 ± 2. 257,1 ± 2.
9. Procédé selon l'une quelconque de la revendication 2 et des revendications 3 à 8 lorsque
relevant de la revendication 2, dans lequel les ions de SIL-Angl sont sélectionnés
dans le groupe consistant d'ions ayant un rapport masse sur charge de 524, 3 ± 2.779,5
± 2, et de 269,2 ± 2.
10. Procédé selon l'une quelconque des revendications 1 à 9, consistant en outre à terminer
l'activité rénine plasmatique en amont de l'étape de digestion protéasique ; et éventuellement
dans lequel du méthanol est ajouté à l'échantillon pour terminer l'activité rénine
plasmatique ; et éventuellement consistant en outre à évaporer le méthanol et à reconstituer
ensuite l'échantillon dans un tampon avant de passer à l'étape de la digestion protéasique.
11. Procédé selon l'une quelconque des revendications 1 à 10, dans lequel le produit de
clivage d'Angl, et le produit de clivage facultatif de SIL-Angl font l'objet d'une
chromatographie liquide avant de faire l'objet d'une spectrométrie de masse, et/ou
dans lequel l'ionisation est une ionisation par électronébulisation en mode positif
selon une mesure de réactions sélectionnées (SRM).
12. Procédé selon l'une quelconque des revendications 1 à 11, dans lequel l'échantillon
est un fluide biologique provenant d'un patient ; et éventuellement dans lequel le
fluide biologique est du plasma ; et éventuellement dans lequel le fluide biologique
comprend de l'acide éthylènediaminetétraacétique (EDTA) comme coagulant.
13. Procédé selon l'une quelconque des revendications 1 à 12, consistant en outre avant
l'étape d'incubation pour générer de l'Angl à supprimer un aliquot de l'échantillon
et à tester l'aliquot pour vérifier la présence d'EDTA ; et éventuellement dans lequel
le test de la présence d'EDTA comprend l'ajout d'un agent colorimétrique, une complexone
o-crésolphtaléine, en vue d'une réaction avec des ions de calcium dans l'échantillon,
de sorte que la couleur des échantillons contenant de l'EDTA demeure essentiellement
inchangée, alors que les échantillons qui ne contiennent pas d'EDTA changent de couleur
suite à une réaction du calcium sous l'effet de l'agent colorimétrique.
14. Procédé selon l'une quelconque des revendications précédentes, dans lequel le niveau
de l'activité rénine plasmatique est calculé d'après le montant de l'Angl que contient
l'échantillon ; et éventuellement dans lequel l'activité rénine plasmatique est définie
par le montant d'Angl généré par unité de temps, ou dans lequel l'activité rénine
plasmatique est exprimée en ng/mL/h, et/ou dans lequel l'activité rénine plasmatique
comprend une gamme analytiquement mesurable (AMR) allant de 0,167 à 66,667 ng/mL/h,
et/ou dans lequel la limite inférieure de quantification (LLOQ) de l'activité rénine
plasmatique est de 0,167 ng/mL/h et la limite supérieure de quantification (ULOQ)
de l'activité rénine plasmatique est de 66,667 ng/mL/h.
15. Système destiné à déterminer un niveau d'Angl et/ou une activité de rénine plasmatique
dans un échantillon dans le procédé selon l'une quelconque des revendications 1 à
14, le système comprenant :
(a) une station d'incubation de l'échantillon sous des conditions permettant de générer
de l'Angl à partir d'angiotensinogène ;
(b) éventuellement, une station pour ajouter du peptide Angl marqué par isotope stable
(SIL-Angl) à l'échantillon ;
(c) éventuellement, une station pour terminer la génération d'Angl médiée par rénine
plasmatique ;
(d) une station pour digérer l'Angl et éventuellement du SIL-Angl ajouté pour générer
des produits de clivage définis de chaque Angl et de chaque éventuel SIL-Angl ;
(e) une station pour ioniser les produits de clivage définis de l'Angl et de l'éventuel
SIL-Angl pour générer une phase gazeuse d'ions à charge multiple du produit de clivage
d'Angl défini et du produit de clivage de SIL-Angl défini ; et
(f) une station pour analyser la phase gazeuse d'ions à charge multiple par spectrométrie
de masse pour déterminer la présence et/ou le montant du produit de clivage d'Angl
défini et du produit de clivage de SIL-Angl défini dans l'échantillon, dans lequel
le montant des produits de clivage définis témoigne de l'activité rénine plasmatique
dans l'échantillon ; et éventuellement comprenant en outre une station pour tester
la présence d'EDTA dans l'échantillon ; et/ou comprenant en outre une station pour
séparer par chromatographie les produits de clivage définis en ayant recours à de
la chromatographie liquide.