Inhibition of a Heart-Specific Enzyme After a Heart Attack Decreases Heart Damage and Prevents Remodeling


Cardiac Troponin I-interacting Kinase or TNNI3K is an enzyme that was initially identified in fetal and adult heart tissue, but was undetectable in other tissues. The function of this enzyme remains unknown, but Chinese scientists showed that overexpression of TNNI3K in cultured heart muscle cells causes them to blow up and get large (hypertrophy). Earlier this year, a research team from Peking Union Medical College showed that overexpression of TNNI3K in mice caused enlargement of the heart (Tang H., et al., J Mol Cell Cardiol 54 (2013): 101-111). These results suggested that TNNI3K is a potential therapeutic target for heart attack patients.

To that end, Ronald Vagnozzi and his colleagues in the laboratory of Thomas Force at Temple University School of Medicine and their collaborators designed small molecules that can inhibit TNNI3K activity, and these small molecules decrease cardiac remodeling after a heart attack in rodents. Large animal trials are planned next.

In the first experiments of this paper, Vagnozzi and others showed that the levels of TNNI3K in the heart increase after a heart attack. Measurements of TNNI3K protein levels failed to detect it in all tissue other than the heart. Furthermore, it was present throughout the heart, and mainly in heart muscle and not in blood vessels, fibroblasts, and other types of non-muscle heart tissues.

Next, Vagnozzi and others measured TNNI3K protein levels in heart transplant patients. The heart tissues of these patients, who had badly dysfunctional hearts showed higher than usual levels of TNNI3K protein. Thus, TNNI3K is associated with heart tissue and is up-regulated in response to heart dysfunction.

The next experiment examined the effects of overexpressing the human TNNI3K gene in mice. While the overexpression of TNNI3K did not affect heart function of structure under normal circumstances, under pathological conditions, however, this is not he case. If mice that overexpressed TNNI3K where given heart attacks and then “reperfused,” means that the blood vessel that was tied off to cause the heart attack was opened and blood flowed back into the infarcted area. In these cases, mice that overexpressed TNNI3K had a larger area of cell death in their hearts than their counterparts that did not overexpress TNNI3K. The reason for this increased cell death had to do with the compartment in the cell that generated most of the energy – the mitochondrion. TNNI3K causes the mitochondria in heart muscle cells to go haywire and kick out all kinds of reactive oxygen-containing molecules that damage cells.

Cell damage as a result of reactive oxygen-containing molecules (known as reactive oxygen species or ROS) activates a pathway in heart cells called the “p38” pathway, which leads to programmed cell death.

p38 signaling

Once Vagnozzi and his colleagues nailed down the function of TNNI3K in heart muscle cells after a heart attack, they deleted the gene that encodes TNNI3K and gave those TNNI3K-deficient mice heart attacks. Interestingly enough, after a heart attack, TNNI3K-deficient mice showed much small dead areas than normal mice. Also, the levels of the other mediators of TNNI3K-induced cell death (e.g., oxygen-containing molecules, p38, ect.) were quite low. This confirms the earlier observations that TNNI3K mediates the death of heart muscle cells after a heart attack, and inhibiting TNNI3K activity decreases the deleterious effects of a heart attack.

And now for the pièce de résistance – Vagnozzi and his crew synthesized small molecules that inhibited TNNI3K in the test tube. Then they gave mice heart attacks and injected these molecules into the bellies of the mice. Not only were the infarcts, or areas of dead heart muscle cells small in the mice injected with these TNNI3K inhibitors, but the heart of these same mice did not undergo remodeling and did not enlarge, showed reduced scarring, and better ventricular function. This is a proof-of-principle that inhibiting TNNI3K can reduce the pathological effects of a heart attack.

This strategy must be tested in large animals before it can move to human trials, but the strategy seems sound at this point, and it may revolutionize the treatment of heart attack patients.

Primed Fat-Based Stem Cells Enhance Heart Muscle Proliferation


A Dutch group from the University of Groningen has shown that fat-based stem cells can enhance the proliferation of cultured heart muscle cells. The stem cells used in these experiments were preconditioned and this pretreatment greatly enhanced their ability to activate heart muscle cells.

This paper, by Ewa Przybyt, Guido Krenning, Marja Brinker, and Martin Harmsen was published in the Journal of Translational Medicine. To begin, Przybyt and others extracted human adipose derived stromal cells (ADSC) from fat tissue extracted from human liposuction surgeries. To do this, they digested the fat with enzymes, centrifuged and washed it, and then grew the remaining cells in culture.

Then they used rat neonatal heart muscle cells and infected them with viruses that causes them to glow when certain types of light was shined on them. Then Przybyt and others co-cultured these rat heart cells with human ADSCs.

In the first experiment, the ADSCs were treated with drugs to prevent them from dividing and then they were cultured with rat heart cells in a one-to-one ratio. The heart muscle cells grew faster with the ADSCs than they did without them. To determine if cell-cell contact was required for this stimulation, they used the culture medium from ADSCs and grew the heart cell on this culture medium. Once again, the heart cells grew faster with the ADSC culture medium than without it. These results suggest that the ADSCs stimulate heart cell proliferation by secreting factors that activate heart cell division.

Another experiment subjected the cultured heart cells to the types of conditions they might experience inside the heart after a heart attack. For example, heart cells were subjected to low oxygen tensions (2% oxygen), and inflammation – two conditions found within the heart after a heart attack. These treatments slowed heart cell growth, but this heart cell growth was restored by adding the growth medium of ADSCs. Even more remarkably, when ADSCs were grown in low-oxygen conditions or treated with inflammatory molecules (tumor necrosis factor-alpha or interleukin-1beta), the culture medium increased the fractions of cells that grew. Therefore, ADSCs secrete molecules that increase heart muscle cell proliferation, and increase proliferation even more after the ADSCs are preconditioned by either low oxygen tensions or inflammation.

In the next experiment, Przybyt and others examined the molecules secreted by ADSCs under normal or low-oxygen tensions to ascertain what secreted molecules stimulated heart cell growth. It was clear that the production of a small protein called interleukin-6 was greatly upregulated.

Could interleukin-6 account for the increased proliferation of heart cells? Another experiment showed that the answer was yes. Cultured heart cells treated with interleukin-6 showed increased proliferation, and when antibodies against interleukin-6 were used to prevent interleukin-6 from binding to the heart cells, these antibodies abrogated the effects of interleukin-6.

Przybyt and others then took these results one step further. Since the signaling pathways used by interleukin-6 are well-known, they examined these pathways. Now interleukin-6 signals through pathways, once of which enhances cell survival, and another pathway that stimulated cell proliferation. The cell proliferation pathway uses a protein called “STAT3” and the survival function uses a protein called “Akt.” Both pathways were activated by interleukin-6. Also, the culture medium of ADSCs that were treated with interleukin-6 induced the interleukin-6 receptor proteins (gp80 and gp130) in cultured heart muscle cells. This gives heart muscle cells a greater capacity to respond secreted interleukin-6.

This paper shows that stromal stem cells from fat has the capacity, in culture, to activate the growth of cultured heart muscle cells. Also, if these cells were preconditioned with low oxygen tensions or pro-inflammatory molecules, those fat-based stem cells secreted interleukin-6, which enhanced heart muscle cell survival, and proliferation, even if those heart muscle cells are exposed to low-oxygen tensions or inflammatory molecules.

This suggests that preconditioned stem cells from fat might be able to protect heart muscle cells and augment heart healing after a heart attack. Alternatively, cardiac administration of interleukin-6 after a heart attack might prove even more effective to protect heart muscle cells and stimulate heart muscle cell proliferation. Human trials anyone?