Scientists studied sheep to understand how a mother’s diet before pregnancy affects her babies’ fat tissue development. They found that when mothers didn’t eat enough protein early in life, their offspring developed fat cells differently—even before birth. The babies showed signs of making more fat cells and being more likely to store fat later in life. This research helps us understand how what parents eat can affect their children’s bodies, with possible lessons for both farm animals and humans.

The Quick Take

  • What they studied: How a mother sheep’s low-protein diet before having babies affects the fat tissue development of her lambs
  • Who participated: 16 lambs total: 8 born to mothers who ate low-protein diets and 8 born to mothers who ate normal diets. Scientists looked at fat tissue from the area around their kidneys
  • Key finding: Lambs born to protein-restricted mothers showed increased activity in genes related to making new fat cells, suggesting they may be programmed to store more fat throughout their lives
  • What it means for you: This suggests that a mother’s nutrition before pregnancy may influence how her children’s bodies handle fat storage. However, this was studied in sheep, so more research is needed to confirm if the same happens in humans

The Research Details

Researchers used a technique called RNA-Seq, which is like reading the instruction manual inside cells to see which genes are turned on or off. They collected fat tissue samples from lambs and compared the genes in lambs born to mothers with low-protein diets versus normal diets. They also separated lambs into two groups: those that naturally stored more fat and those that stored less fat. This allowed them to see both how the mother’s diet affected genes AND how natural fat-storing ability affected genes.

The scientists then did a meta-analysis, which means they combined their findings to identify patterns. They looked for genes that were consistently different between the two groups and genes that seemed to respond specifically to the mother’s low-protein diet.

By looking at the actual genes being used in fat tissue, researchers can understand the biological mechanisms—the ‘why’ behind what happens. This is more detailed than just measuring how much fat the animals have. Understanding these mechanisms helps scientists predict long-term health effects and develop better nutrition strategies.

This study used a well-established scientific technique (RNA-Seq) published in a reputable journal (Scientific Reports). The sample size was small (16 lambs), which is typical for detailed genetic studies but means results should be confirmed with larger studies. The research was conducted in sheep, which are good models for human nutrition but aren’t identical to humans. The findings are based on gene activity patterns, which suggest potential effects but don’t prove they will definitely occur in real life.

What the Results Show

The researchers identified 219 genes that were consistently linked to how much fat the lambs stored. In lambs that naturally stored more fat, genes related to building new blood vessels in fat tissue were more active. In lambs that stored less fat, genes involved in creating new fat cells were more active.

When they looked specifically at lambs born to protein-restricted mothers, they found 215 genes that responded to this maternal diet. These genes were mostly involved in making new fat cells and increasing the ability to store fat. Importantly, this pattern appeared in both the lambs that naturally stored more fat AND those that stored less fat—meaning the mother’s diet affected all her offspring similarly.

This suggests that maternal protein restriction ‘programs’ the offspring’s fat tissue to be more active at making and storing fat, regardless of the lamb’s natural tendency. The effect appears to happen before birth or very early in life, setting up patterns that may persist into adulthood.

The study revealed that fat tissue development happens in distinct stages. Early stages involve building the blood vessel network that supplies fat tissue, while later stages focus on creating new fat cells. The mother’s low-protein diet seemed to shift the balance toward more fat cell creation. This finding is important because it shows that maternal nutrition doesn’t just affect how much fat babies have at birth—it changes how their fat tissue is organized and functions.

Previous research has shown that maternal nutrition affects offspring health, but most studies looked at the overall effects on body weight or disease risk. This study goes deeper by examining the actual genetic changes in fat tissue. The findings align with the concept of ‘developmental programming,’ where early-life conditions set up patterns that affect health later. However, most previous studies in this area were done in rodents or looked at severe malnutrition, so this sheep study provides new information about moderate protein restriction in a larger animal model.

The study was conducted in sheep, not humans, so we can’t directly apply these findings to people without further research. The sample size was small (16 lambs), which limits how confident we can be in the results. The study only looked at fat tissue from one location in the body (around the kidneys), so we don’t know if the same patterns occur in other fat deposits. The researchers measured gene activity but didn’t follow the lambs long-term to see if these genetic changes actually led to more fat storage as they grew up. Finally, the study doesn’t tell us how much protein restriction is needed to cause these changes or whether the effects can be reversed with better nutrition later in life.

The Bottom Line

Based on this research, it appears that adequate protein nutrition during childhood and before pregnancy may be important for normal fat tissue development in offspring. However, this is preliminary evidence from animal studies. Current recommendations to eat enough protein during pregnancy and childhood remain supported by this research but shouldn’t be changed based solely on this study. Anyone concerned about their nutrition or their children’s health should consult with a healthcare provider or registered dietitian.

This research is most relevant to: pregnant women and women planning pregnancy (adequate protein intake appears important), parents interested in understanding how early nutrition affects their children’s long-term health, livestock farmers and veterinarians (for improving breeding and nutrition strategies), and researchers studying how early-life nutrition affects lifelong health. This research is NOT a reason for people to drastically change their diets or for people without pregnancy plans to worry about their mothers’ diets from decades ago.

If these findings apply to humans, the effects would likely begin before birth and continue developing through childhood. Changes in a mother’s nutrition during pregnancy might affect her baby’s fat tissue development, but we don’t know how long it takes for these genetic changes to result in noticeable differences in body composition. Long-term follow-up studies would be needed to determine this timeline.

Want to Apply This Research?

  • For pregnant users or those planning pregnancy: Track daily protein intake (target grams per day) and compare to recommended amounts. For parents: Monitor children’s growth patterns and body composition changes over time using regular measurements, noting any correlations with family nutrition patterns.
  • Users could set daily protein intake goals based on their life stage (pregnancy, planning pregnancy, or general health) and log meals to ensure adequate protein consumption. The app could provide reminders about protein-rich foods and track consistency over weeks and months.
  • Establish baseline protein intake and body composition measurements, then track monthly or quarterly. For pregnant users, monitor protein intake throughout pregnancy. For parents, track children’s growth metrics annually and correlate with family nutrition patterns over years to identify long-term trends.

This research was conducted in sheep and represents preliminary evidence about how maternal nutrition may affect offspring fat tissue development. These findings have not been directly tested in humans. This information should not be used to diagnose, treat, or prevent any health condition. Pregnant women, women planning pregnancy, and parents should consult with their healthcare provider or registered dietitian for personalized nutrition advice. The presence of gene activity changes does not guarantee that health problems will develop. Individual genetics, overall diet, physical activity, and many other factors also influence body composition and health.