Scientific Societies Advancing STEM Workforce Diversity: Lessons and Outcomes from the Minorities Affairs Committee of the American Society for Cell Biology.

Promoting diversity and inclusiveness in the STEM academic workforce remains a key challenge and national priority. Scientific societies can play a significant role in this process through the creation and implementation of programs to foster STEM academic workforce diversification, and by providing mentoring and skills development training that empower scientists from under-represented minority (URM) backgrounds to succeed in their communities of practice. In this article, we provide examples of challenges met by scientific societies in these areas and present data from the American Society for Cell Biology, highlighting the benefits received by trainees through long-term engagement with its programs. The success of these initiatives illustrates the impact of discipline-specific programming by scientific societies in supporting the development of URM scientists and an increasingly diverse and inclusive academic STEM community.

The effects of folate intake on DNA and single-carbon pathway metabolism in the fruit fly Drosophila melanogaster compared to mammals.

Mechanisms of vitamin function in non-mammals are poorly understood, despite being essential for development. Folate and cobalamin are B-vitamin cofactors with overlapping roles in transferring various single-carbon units. In mammals, one or both is needed for nucleotide synthesis, DNA methylation, amino acid conversions and other reactions. However, there has been little investigation of the response to folate or cobalamin in insects. Here, we manipulated folate intake and potentially cobalamin levels in the fruit fly Drosophila melanogaster with chemically-defined diets, an antibiotic to reduce bacterially-derived vitamins, and the folate-interfering pharmaceutical methotrexate, to see if single-carbon metabolites and DNA synthesis rates would be affected. We found that similar to mammals with low folate intake, fruit fly larvae had significantly slower growth and DNA synthesis rates. But changes to single carbon-metabolites did not mirror that of mammals with abnormal folate or given MTX. Five of the nine metabolites measured were not significantly affected (methionine, serine, glycine, methylglycine, and dimethylglycine) and three (cystathionine, methylgycine, and methylmalonic acid) were only decreased in larvae consuming methotrexate. Metabolites expected to be elevated if flies used cobalamin from microbial symbionts were not affected by dietary sulfaquinoxaline. Our data support the role of folate in nucleotide synthesis in D. melanogaster and that microbial symbionts provide functioning folates. We could not confirm how folate intake affects single carbon pathway metabolites, nor whether Drososphila use microbially-derived cobalamin. Further work should explore which cofactors are used in fruit flies in these important and potentially novel pathways.

Effects of dietary folic acid level and symbiotic folate production on fitness and development in the fruit fly Drosophila melanogaster.

Folic acid is a vitamin for probably all animals. When converted to folate forms, it is used in DNA synthesis and amino acid metabolism. Literature suggests insects must consume folates, folates do not affect others, is a toxin for some, and that a few insects synthesize it. It has been reported that Drosophila melanogaster does not consistently need dietary folate because it can synthesize it. This seems unlikely since animals generally lack this ability. More likely, folates thought to have been made by the fly came from microbial symbionts. We aimed to clarify how dietary folic acid affects fitness and development in fruit flies and whether flies may receive folates from microbial symbionts. We found larvae were more viable and developed faster with increasing dietary folic acid, with the surprising exception that larvae fed nearly-zero folic acid developed faster. Their body folate levels did not significantly differ from those that consumed up to 600 times more folic acid. However, these flies fed little folate only achieved normal body folate levels and development times when antibiotics were excluded from the diet. When flies consumed near-zero folates with antibiotics, their body folate levels decreased and development was prolonged. An assay for the endosymbiont Wolbachia in flies used to generate the experimental flies did not show presence of these bacteria. Our data suggest D. melanogaster can harbor unknown bacterial symbiont(s) that provide essential folates to their host when it is scarce in the diet, allowing the fruit fly to maintain growth and development.