iPS-cell-derived microglia promote brain organoid maturation via cholesterol transfer.

Microglia are specialized brain-resident macrophages that arise from primitive macrophages colonizing the embryonic brain1. Microglia contribute to multiple aspects of brain development, but their precise roles in the early human brain remain poorly understood owing to limited access to relevant tissues2-6. The generation of brain organoids from human induced pluripotent stem cells recapitulates some key features of human embryonic brain development7-10. However, current approaches do not incorporate microglia or address their role in organoid maturation11-21. Here we generated microglia-sufficient brain organoids by coculturing brain organoids with primitive-like macrophages generated from the same human induced pluripotent stem cells (iMac)22. In organoid cocultures, iMac differentiated into cells with microglia-like phenotypes and functions (iMicro) and modulated neuronal progenitor cell (NPC) differentiation, limiting NPC proliferation and promoting axonogenesis. Mechanistically, iMicro contained high levels of PLIN2+ lipid droplets that exported cholesterol and its esters, which were taken up by NPCs in the organoids. We also detected PLIN2+ lipid droplet-loaded microglia in mouse and human embryonic brains. Overall, our approach substantially advances current human brain organoid approaches by incorporating microglial cells, as illustrated by the discovery of a key pathway of lipid-mediated crosstalk between microglia and NPCs that leads to improved neurogenesis.

Vaccination and associated factors among tribal children of 1 year age in nine Indian districts: A cross-sectional study.

OBJECTIVE: To report on vaccination status by 12 months of age among tribal children from nine districts of India. METHODS: Cross-sectional study of 2631 tribal women having a child aged 12 months or below from nine Indian districts with a considerable proportion of the tribal population. Socio-demographic details, reception of various vaccines by 12 months of age, mother's antenatal care utilisation and health system-related details were collected through a pre-tested, interviewer-administered questionnaire from mothers. Multiple logistic regression analysis was used to identify the factors associated with complete vaccination by 12 months of age. RESULTS: Only 52% of children were fully vaccinated by the age of 12 months among the tribal populations; 11% did not receive any vaccine, and 37% of the tribal children received some vaccines. The age-appropriate vaccination was unsatisfactory as only 75% of the infants received all birth dose vaccines, and only 60.5% received all doses by 14 weeks. Only 73% were vaccinated against measles. Illness of the child, home births and communication gaps concerning vaccination were the main reasons for an infant not being vaccinated appropriately. Frequency of health worker's visits to the village, hospital birth, reception of advice on vaccination and educational status of the head of the households were significantly associated with full vaccination status. CONCLUSION: A relatively low proportion of children were fully vaccinated among the tribal populations. Health systems factors, mainly the outreach services and advice by the health workers, were positively and significantly associated with a child being fully vaccinated by 12 months of age. Improving outreach services is crucial to improve vaccination coverage in tribal areas, and there is a need to address the social determinants in the long run.

Mitochondrial Control of Stem Cell State and Fate: Lessons From Drosophila.

Over the years, Drosophila has served as a wonderful genetically tractable model system to unravel various facets of tissue-resident stem cells in their microenvironment. Studies in different stem and progenitor cell types of Drosophila have led to the discovery of cell-intrinsic and extrinsic factors crucial for stem cell state and fate. Though initially touted as the ATP generating machines for carrying various cellular processes, it is now increasingly becoming clear that mitochondrial processes alone can override the cellular program of stem cells. The last few years have witnessed a surge in our understanding of mitochondria's contribution to governing different stem cell properties in their subtissular niches in Drosophila. Through this review, we intend to sum up and highlight the outcome of these in vivo studies that implicate mitochondria as a central regulator of stem cell fate decisions; to find the commonalities and uniqueness associated with these regulatory mechanisms.

Fatty acid ß-oxidation is required for the differentiation of larval hematopoietic progenitors in Drosophila.

Cell-intrinsic and extrinsic signals regulate the state and fate of stem and progenitor cells. Recent advances in metabolomics illustrate that various metabolic pathways are also important in regulating stem cell fate. However, our understanding of the metabolic control of the state and fate of progenitor cells is in its infancy. Using Drosophila hematopoietic organ: lymph gland, we demonstrate that Fatty Acid Oxidation (FAO) is essential for the differentiation of blood cell progenitors. In the absence of FAO, the progenitors are unable to differentiate and exhibit altered histone acetylation. Interestingly, acetate supplementation rescues both histone acetylation and the differentiation defects. We further show that the CPT1/whd (withered), the rate-limiting enzyme of FAO, is transcriptionally regulated by Jun-Kinase (JNK), which has been previously implicated in progenitor differentiation. Our study thus reveals how the cellular signaling machinery integrates with the metabolic cue to facilitate the differentiation program.

Stem cells are special precursor cells, found in all animals from flies to humans, that can give rise to all the mature cell types in the body. Their job is to generate supplies of new cells wherever these are needed. This is important because it allows damaged or worn-out tissues to be repaired and replaced by fresh, healthy cells. As part of this renewal process, stem cells generate pools of more specialized cells, called progenitor cells. These can be thought of as half-way to maturation and can only develop in a more restricted number of ways. For example, so-called myeloid progenitor cells from humans can only develop into a specific group of blood cell types, collectively termed the myeloid lineage. Fruit flies, like many other animals, also have several different types of blood cells. The fly's repertoire of blood cells is very similar to the human myeloid lineage, and these cells also develop from the fly equivalent of myeloid progenitor cells. These progenitors are found in a specialized organ in fruit fly larvae called the lymph gland, where the blood forms. These similarities between fruit flies and humans mean that flies are a good model to study how myeloid progenitor cells mature. A lot is already known about the molecules that signal to progenitor cells how and when to mature. However, the role of metabolism ­ the chemical reactions that process nutrients and provide energy inside cells ­ is still poorly understood. Tiwari et al. set out to identify which metabolic reactions myeloid progenitor cells require and how these reactions might shape the progenitors' development into mature blood cells. The experiments in this study used fruit fly larvae that had been genetically altered so that they could no longer perform key chemical reactions needed for the breakdown of fats. In these mutant larvae, the progenitors within the lymph gland could not give rise to mature blood cells. This showed that myeloid progenitor cells need to be able to break down fats in order to develop properly. These results highlight a previously unappreciated role for metabolism in controlling the development of progenitor cells. If this effect also occurs in humans, this knowledge could one day help medical researchers engineer replacement tissues in the lab, or even increase our own bodies' ability to regenerate blood, and potentially other organs.