Russians born during the Leningrad Siege in World War II, which was responsible for some of the greatest losses of civilian life in history, are giving scientists new strategies to identify people who experienced intrauterine growth restriction (IUGR) and starvation during childhood at greatest risk of developing long term heart complications. The abstract study¹, presented at the Frontiers in CardioVascular Biology (FCVB) meeting, in London, UK, 30 March to 1 April 2012, makes use of a unique population of people exposed to extreme starvation both as foetuses and during childhood.
The cellular changes identified, investigators suggested, might be used to target treatments to children at greatest risk of developing heart complications. In a second study ², also presented at FCVB 2012, Spanish investigators elucidated structural changes occurring in the heart as a direct consequence of IUGR. Monitoring reversal of these changes, suggested the authors, might offer a “fast track” approach for testing effectiveness of new therapies.
“Together, these innovative studies demonstrate the impact that basic research can have on the development of new approaches to heart treatments,” said Sian Harding, FCVB 2012 chairperson of the Core Scientific Committee. “New treatments preventing heart changes associated with poor nutrition would benefit those exposed to IUGR and also children who’ve experienced reduced calorie intakes, either due to food shortages or extreme dieting.”
Intrauterine growth restriction (IUGR), defined as a birth weight below the 10th percentile for gestational age, currently has an incidence estimated to be 8.1% of births in developed countries, and 6 to 30% of births in developing countries. Common causes include chronically malnourished mothers, maternal health problems during pregnancy (such as diabetes) and placentas that fail to transfer adequate nutrients from mother to foetus.
The connection between IUGR and development of subsequent heart disease was first recognised in 1989 when David Barker, from the MRC Unit at the University of Southampton, UK, showed that the lower the weight of a baby at birth and during infancy, the higher the risk of developing cardiovascular disease (CVD) and other chronic conditions in later life ³. IUGR newborns show signs of CV remodelling and dysfunction, including reduced myocardial velocities, dilated hearts and increased thickness of artery walls.
Studies have shown that children with IUGR have a distinct cardiac morphology, with “less elongated and more globular” cardiac ventricles. “As a consequence IUGR hearts are not as efficient in generating the normal stroke volumes, which results in the need for an increased heart rate to maintain cardiac outputs. The overall result is less efficient hearts,” explained Iratxe Torre, one of the investigators, from The Hospital Clinic of Barcelona, Spain.
No treatments are currently available to reverse the structural heart changes resulting from IUGR.
Telomere length provides CVD insights in survivors of Leningrad Siege.
In abstract P190 investigators from the Almazov Federal Heart, Blood and Endocrinology Centre, St Petersburg, Russian Federation, studied the telomere length of survivors from the siege of Leningrad (1941 to 1944), which was responsible for citizens being subjected to some of the most extreme levels of starvation known in history ¹.
“For workers the bread ration was 250g, which amounted to just 300 calories, with around half that for the rest of the population,” said Olga Freylikhman, one of the study investigators. The diet, she added, contained virtually no protein. By the end of the siege out of a population of 2.9 million, including 0.5 million children, over 630,000 people had died from hunger related causes.
Telomeres are the DNA-protein complexes that encase the ends of chromosomes. Often likened to the plastic caps on shoelaces, they serve the function of promoting chromosome stability. Consistently shortened telomere lengths have been associated with health risk and disease – one study showed that mean telomere lengths (measured in blood DNA) predicted the 15 year risk of CVD mortality, and others identified shorter telomeres among subjects who smoked, had elevated blood pressure, and premature myocardial infarctions (MIs).
Identification of survivors for the study was made possible by the fact that after World War II, inhabitants of Leningrad (now St Petersburg) who survived the siege were invited to join special support societies. From these societies, still in existence today, investigators have been able to recruit 40 subjects born during the siege, and 260 born before the siege who had lived through the deprivations as children. Survivors were compared to age matched controls born during the same period (1930 to 1943) and now living in St Petersburg, but who had not been exposed to siege conditions. All subjects were asked to fill in questionnaires regarding lifestyle factors and take part in a range of tests including blood pressure measurements, fasting lipids and glucose tests, carotid ultrasound, arterial stiffness, and cognitive function, as well as measurements of their telomere lengths by quantitative PCR.
While measurements of telomere length for all subjects are now in progress, preliminary results (presented in the abstract) comparing the telomere length of survivors of the siege (n=106), with controls (n=27) show that survivors had significantly shorter telomere lengths (p<0.005). Furthermore investigators found a higher prevalence of current metabolic disorders among siege survivors. No difference in telomere length, however, was found between the 20 subjects born during the siege and the 86 born before the siege.
“Our results suggest that measuring telomere length might ultimately be used as a way to stratify heart risk in people who’ve experienced both intrauterine starvation and food shortages during childhood. Those found to be at high risk could be managed using aggressive prevention measures,” said Freylikhman.
One possible explanation for the lack of differences found between subjects exposed to intrauterine shortages and those experiencing childhood starvation, suggested Freylikhman, is that the people with IUGR who have shorter telomere lengths were more likely to have died immediately following the siege.
Further studies are planned to explore differences in telomere length according to the ages of children at the time of siege, and to explore whether telomere length and metabolic disorders affect the offspring of survivors of the siege.
Spanish team documents IUGR changes to heart muscle architecture
In the second study Iratxe Torre and colleagues set out to identify the changes that occur to the cardiac muscle “architecture” following IUGR ². The investigators, from The Hospital Clinic of Barcelona, Spain, used an animal model of IUGR based on the selective ligature of the uteroplacental vessels in pregnant rabbits that restrict blood flow to the foetus.
“Rabbits represent an ideal model for IUGR. They have similar placenta structure and heart muscle compositions to humans and possess a two-horned uterus. Ligatures can be applied to one horn, while the other can be left to provide the perfect experimental control,” explained Torre.
Using Polarization Second Harmonic Generation Microscopy (PSHGM), a technique that is highly sensitive to changes in the molecular organisation of cardiac sarcomeres, the team revealed differences in the position of myosin proteins between IUGR animals and controls.
Sarcomeres, representing the basic contractile unit of cardiac muscle, are composed of the protein actin (which forms the thin filaments) and the protein myosin (which forms the thick filament). Actin and myosin slide past each other when muscles contract and relax.
The Spanish team found that the distance between the myosin molecules inside the thick filaments (known as the helical pitch angle) was increased slightly in the IUGR rabbit muscle (by around two nanometres) immediately following birth in comparison to the normal controls. The displacement, persisted when young adults were examined again 70 days after birth.
“Our work suggests the 3D conformation of myosin within the cardiac thick filaments is changed following IUGR,” said Torre. In a second abstract ⁴, she added, the team went on to observe that similar changes occur in the myosin filaments of older rabbits (aged around one year).
“It appears that growth restricted rabbits are born with prematurely old sarcomeres,” said Torre. “Changes to the myosin structure might provide a direct explanation for the adverse CV outcomes found in IUGR.”
Measurements of the helical pitch angle, which documents highly precise changes to the structure and orientation of myosin thick filaments, the investigators suggested, offers a new way to assess the effectiveness of potential treatments to prevent the cardiovascular complications of IUGR in animal models. “Using such a precise approach would allow much faster development of treatments related to both the heart changes occurring in IUGR and cardiomyopathies related to ageing,” said Torre.
1. O Freylikhman, O Rotar, N Chromova, et al. Telomere length in metabolic disorders in group of survivors of Leningrad siege. FPN 536 http://spo.escardio.org/AbstractDetails.aspx?id=102438
2. I Torre, I Amat-Roldan, I Iruretagoiena et al. Intrauterine growth restriction alters myosin thick filaments ultrastructure in cardiac sarcomeres and persists in adult life. FPN 623 http://spo.escardio.org/AbstractDetails.aspx?id=102498
3. D. Barker, C Osmond, PD Winter , et al. Weight in infancy and death from ischaemic heart disease. Lancet 1989, September 9; 2 (8663):577-580.
4. I Torre, S Psilodimitrakopoulos, S Iruretagoyena et al. Helical pitch angle of myosin thick filaments correlates with aging and beta myosin heavy chain isoform distribution. FPN 418 http://spo.escardio.org/AbstractDetails.aspx?id=102323&eevtid=51