Masonic Medical Research Institute (MMRI) is a non-profit medical research center located in
Utica, New York. The Institute's research and staff are independent, but gets its name from its original funding in 1958 by the
MasonicGrand Lodge of New York.[1]
The campus of Masonic Medical Research Institute is in Utica, New York, and the facility includes several labs and advanced research equipment. The core facilities include:
Genetics Core: The Molecular Genetics Core studies the human
genome and identifies the factors that are responsible for diseases.[2] Genetics Core equipment includes:
Imaging Core: The Advanced Imaging Core at MMRI was developed to facilitate the non-invasive analysis of preclinical models of disease.[3] Equipment includes:
Perkin Elmer IVIS Spectrum –
2D and
3D optical imaging
Nikon Ni-E Research Microscope System – upright microscope – fluorescence, brightfield, and polarized light
FACS (
Flow Cytometry Core): The Flow Cytometry Core (FCC) at MMRI provides instrumentation and expertise in a broad range of basic and medical science disciplines.[5]
Funding
Besides funding from the Grand Lodge of New York and private donations, the MMRI has recently received funding from the New York state government.
In the January 2022
State of the State address, New York Governor
Kathy Hochul proposed state funding for a new 32,000-square-laboratory at MMRI, which would establish the MMRI as a "biomedical
incubator to accelerate
commercialization of basic research."[7] Additional state funding for MMRI is currently being proposed in the
New York State Legislature in a
bipartisan effort including Democrats and Republicans.[8]
Education and partnerships
The MMRI offers a
Postdoctoral Fellowship Program as well as a Predoctoral Research Training Program which is administered in affiliation with
SUNY Upstate Medical University at Syracuse, New York. Its ten-week Summer Fellowship Program, initiated in 1960, provides hands-on experience in research to students in the life sciences.[9]
MMRI operates Mentoring Programs with
BOCES, tours and shadowing programs to provide information to high school students about careers in science and research. In addition, they have partnered with
Mohawk Valley Health System for key initiatives benefiting the local community.[10] In 2020 and 2021 during the
COVIDpandemic, MMRI's large size and capability made it an ideal center for
COVID testing.[11]
Current research
Masonic Medical Research Institute has five Principal Investigators, each with their own lab and team, they are:
Dr. Maria Kontaridis: The Kontaridis Lab's focus is on molecular
signaling pathways that lead to aberrant regulation of embryonic development and mediate onset of adult disease. Research areas include
autism,
lupus, and
Noonan Syndrome. Kontaridis is also MMRI's
Executive Director and the Gordon K. Moe Professor and Chair for Biomedical Research and Translational Medicine at MMRI. She is an Associate Professor of Medicine, part-time at
Beth Israel Deaconess Medical Center at
Harvard Medical School.[12]
Dr. Zhiqiang Lin: The Lin Lab researches how heart tissue and
brown fat tissue grow and react to stress, especially focusing on
Hippo-YAP cell signaling, which is relevant to reducing
cardiovascular diseases and
obesity. A better understanding of brown fat (brown adipose tissue) can also help us better understand
body heat regulation,
hypothermia, and
diabetes.[13] Lin's explanation of homeostasis and how brown fat insulates the human body was quoted in an article about
cold-water swimming, in an article titled, "Can Our Bodies 'Learn' to Withstand Frigid Temperatures?" published by
HowStuffWorks (owned by
Discovery Channel) in February 2022.[14]
Dr. Jason McCarthy: McCarthy is unique for his work in
nano-imaging,
nano-medicine, and
targeted drug delivery. For example, McCarthy can take a particle as small as 1/1,000th the width of a hair, and place it anywhere needed in the human body.[15]
Dr. Coralie Poizat: The Poizat Lab researches
heart failure and the genetic and
epigenetic mechanisms that cause the heart to fail. Heart failure and cardiovascular disease are the leading cause for death worldwide, more so than cancer. Poizat finds new
pathways relevant to cardiac diseases, which may lead to developing new health therapies.[16]
Dr. Nathan Tucker: The Tucker Lab focuses on
genomic decryption and the study of molecular events, specializing in how this understanding can improve cardiovascular health. Tucker's lab also studies
how SARS/COVID impacts the heart.[17]
Other areas of research at MMRI have included:
Cardiac Electrophysiology – This program uses experimental models to examine the root cause of cardiac arrhythmias (abnormal heart rhythms) and to develop treatments for heart disease.
Molecular Biology – Genes suspected of causing
genetic mutations are cloned and the mutation is inserted into a
heterologousexpression system so that the functional effect of the mutation can be evaluated, to further determine whether the genetic variant is the true cause of the disease.
Stem Cell Research – This program is focused on generating
induced pluripotent stem cells to be used in testing the safety and efficacy of new drugs, and also for the creation of human models of heart disease to improve understanding of arrhythmic syndromes and to custom design treatments and cures.
Organ and Tissue Bioengineering – This is a long-term program studying the use of a combination of pluripotent stem cells and
decellularized donor hearts to created human hearts for transplantation without the problem of
rejection.
In 1960 researchers at MMRI developed a mathematical model for use in the study of
atrial fibrillation. In 1966 they demonstrated dual pathways in the
AV node and showed the basis for AV nodal
tachycardia.
In 1973 Institute researchers showed that
oscillatory after potentials (delayed afterdepolarizations) was the basis for arrhythmias associated with
digitalistoxicity. Over the next several years later they explored modulated
parasystole and reflection as mechanisms of cardiac arrhythmias.
In the 1980s research staff worked to clarify the differences between
epicardium and
endocardium, and found that the presence of an
action potential notch in epicardium, but not endocardium, is responsible for inscription of the electrocardiographic J wave. They found differences in the response of epicardium and endocardium to a variety of drugs and
neurotransmitters.
The MMRI developed a blood substitute which was patented in 1990.
In the 1990s MMRI researchers discovered the
M cell, confirming that the heart is made of several different cell types. In 1998 they uncovered the cellular basis for the various waves that appear on an
electrocardiogram including the J, T and U waves.
Between 1996 and 1998 MMRI published the first gene, SCN5A, to be linked to
idiopathic ventricular fibrillation (IVF). The MMRI named this the Brugada syndrome in 1996, after Josep and Pedro Brugada, who first described this as a new clinical entity in 1992, and in 1999 proposed use of
quinidine and
isoproterenol for its treatment.[20]
In 2000 the MMRI research team uncovered evidence linking
Sudden Infant Death Syndrome to a congenital heart defect, the Long QT syndrome (LQTS) published in
The New England Journal of Medicine. That year they also found experimental evidence, confirmed by later research,[citation needed] that some forms of early repolarization could result in the development of life-threatening arrhythmias.
During the next few years MMRI discovered several genes that when mutated give rise to the Long QT, Short QT, Brugada and Early Repolarization syndromes.[21] They later demonstrated that,
ranolazine (Ranexa), a drug approved for ischemic heart disease, was capable of suppressing both
atrial and ventricular arrhythmias.
In 2007 MMRI researchers studied atrial-selective
sodium channel block as a strategy to manage atrial fibrillation. They later demonstrated that the combination of ranolazine (Ranexa) and
dronedarone (Multaq) could prevent the development of atrial fibrillation, which led to Phase 2
clinical trials.
In 2010 MMRI described “J Wave Syndromes” a subset of inherited cardiac arrhythmia syndromes characterized by accentuated J waves, including the Brugada and Early Repolarization syndromes. Soon after, the research team identified Wenxin Keli, a herbal Chinese medicine, as an atrial selective sodium channel blocker capable of suppressing atrial fibrillation in experimental models. In 2012 they also identified Wenxin Keli and
Milrinone as potential
pharmacological therapies for the Brugada syndrome.