Molecular signatures of cortical expansion in the human fetal brain

The third trimester of human gestation is characterised by rapid increases in brain volume and cortical surface area. A growing catalogue of cells in the prenatal brain has revealed remarkable molecular diversity across cortical areas.1,2 Despite this, little is known about how this translates into the patterns of differential cortical expansion observed in humans during the latter stages of gestation. Here we present a new resource, μBrain, to facilitate knowledge translation between molecular and anatomical descriptions of the prenatal developing brain. Built using generative artificial intelligence, μBrain is a three-dimensional cellular-resolution digital atlas combining publicly-available serial sections of the postmortem human brain at 21 weeks gestation3 with bulk tissue microarray data, sampled across 29 cortical regions and 5 transient tissue zones.4 Using μBrain, we evaluate the molecular signatures of preferentially-expanded cortical regions during human gestation, quantified in utero using magnetic resonance imaging (MRI). We find that differences in the rates of expansion across cortical areas during gestation respect anatomical and evolutionary boundaries between cortical types5 and are founded upon extended periods of upper-layer cortical neuron migration that continue beyond mid-gestation. We identify a set of genes that are upregulated from mid-gestation and highly expressed in rapidly expanding neocortex, which are implicated in genetic disorders with cognitive sequelae. Our findings demonstrate a spatial coupling between areal differences in the timing of neurogenesis and rates of expansion across the neocortical sheet during the prenatal epoch. The μBrain atlas is available from: https://garedaba.github.io/micro-brain/ and provides a new tool to comprehensively map early brain development across domains, model systems and resolution scales.

A lifetime aging study of human CD19 transgenic mice

Mice transgenic for human CD19 have been an important animal model to help understand the role of this molecule in B lymphocyte function. Previously, no lifetime studies had been performed to understand the effects of this CD19 over expression on the survival or spontaneous pathology within the C57BL/6J background strain. We conducted a lifetime study with interim sacrifices to understand the transgenic effects on clinical signs, body weight, survival, and spontaneous pathology. Blood and urine samples were collected from select animals at various time points during the study for measurement of clinical pathology parameters and groups of animals were euthanized and examined at predetermined intervals. There was fair survival with some animals living to 108 weeks of age. Clinical pathology evaluations revealed a declining red cell mass with a regenerative anemia, increasing total white blood cell counts and decreasing glucose level. Total protein, albumin, and globulin levels increased to 52 weeks of age and then declined to or below baseline with advancing age. Increased urinary microalbumin levels correlated with the severity of a glomerulopathy at 76 and 84 weeks of age. Mean body weight increased through 70 weeks and then declined to weights similar to week 28 at 108 weeks. Macroscopic observations included pale kidneys, enlarged seminal vesicles, and enlarged spleens (at 108 weeks of age). The most common neoplasms in this study were bronchiolar alveolar adenomas in the lung, histiocytic sarcoma in several different tissues, and hepatocellular adenomas. The most common non-neoplastic lesions were renal glomerulopathy, and pulmonary lymphocytic infiltrates with increased numbers of alveolar macrophages.

Robust anti-obesity and metabolic effects of a dual GLP-1/glucagon receptor peptide agonist in rodents and non-human primates

AIMS

To characterize the pharmacology of MEDI0382, a peptide dual agonist of glucagon-like peptide-1 (GLP-1) and glucagon receptors.

MATERIALS AND METHODS

MEDI0382 was evaluated in vitro for its ability to stimulate cAMP accumulation in cell lines expressing transfected recombinant or endogenous GLP-1 or glucagon receptors, to potentiate glucose-stimulated insulin secretion (GSIS) in pancreatic β-cell lines and stimulate hepatic glucose output (HGO) by primary hepatocytes. The ability of MEDI0382 to reduce body weight and improve energy balance (i.e. food intake and energy expenditure), as well as control blood glucose, was evaluated in mouse models of obesity and healthy cynomolgus monkeys following single and repeated daily subcutaneous administration for up to 2 months.

RESULTS

MEDI0382 potently activated rodent, cynomolgus and human GLP-1 and glucagon receptors and exhibited a fivefold bias for activation of GLP-1 receptor versus the glucagon receptor. MEDI0382 produced superior weight loss and comparable glucose lowering to the GLP-1 peptide analogue liraglutide when administered daily at comparable doses in DIO mice. The additional fat mass reduction elicited by MEDI0382 probably results from a glucagon receptor-mediated increase in energy expenditure, whereas food intake suppression results from activation of the GLP-1 receptor. Notably, the significant weight loss elicited by MEDI0382 in DIO mice was recapitulated in cynomolgus monkeys.

CONCLUSIONS

Repeated administration of MEDI0382 elicits profound weight loss in DIO mice and non-human primates, produces robust glucose control and reduces hepatic fat content and fasting insulin and glucose levels. The balance of activities at the GLP-1 and glucagon receptors is considered to be optimal for achieving weight and glucose control in overweight or obese Type 2 diabetic patients.

Drosophila: a model for understanding obesity and diabetic complications

The molecular mechanisms underlying development of obesity and diabetic complications are not well understood. Drosophila has become a popular model organism for studying a variety of human diseases. We discuss here emerging Drosophila models of obesity and diabetic complications.

Extension of life-span by loss of CHICO, a Drosophila insulin receptor substrate protein

The Drosophila melanogaster gene chico encodes an insulin receptor substrate that functions in an insulin/insulin-like growth factor (IGF) signaling pathway. In the nematode Caenorhabditis elegans, insulin/IGF signaling regulates adult longevity. We found that mutation of chico extends fruit fly median life-span by up to 48% in homozygotes and 36% in heterozygotes. Extension of life-span was not a result of impaired oogenesis in chico females, nor was it consistently correlated with increased stress resistance. The dwarf phenotype of chico homozygotes was also unnecessary for extension of life-span. The role of insulin/IGF signaling in regulating animal aging is therefore evolutionarily conserved.

Genetic and biochemical characterization of dTOR, the Drosophila homolog of the target of rapamycin

The adaptation of growth in response to nutritional changes is essential for the proper development of all organisms. Here we describe the identification of the Drosophila homolog of the target of rapamycin (TOR), a candidate effector for nutritional sensing. Genetic and biochemical analyses indicate that dTOR impinges on the insulin signaling pathway by autonomously affecting growth through modulating the activity of dS6K. However, in contrast to other components in the insulin signaling pathway, partial loss of dTOR function preferentially reduces growth of the endoreplicating tissues. These results are consistent with dTOR residing on a parallel amino acid sensing pathway.

Genetic control of size in Drosophila

During the past ten years, significant progress has been made in understanding the basic mechanisms of the development of multicellular organisms. Genetic analysis of the development of Caenorhabditis elegans and Drosophila has unearthed a fruitful number of genes involved in establishing the basic body plan, patterning of limbs, specification of cell fate and regulation of programmed cell death. The genes involved in these developmental processes have been conserved throughout evolution and homologous genes are involved in the patterning of insect and human limbs. Despite these important discoveries, we have learned astonishingly little about one of the most obvious distinctions between animals: their difference in body size. The mass of the smallest mammal, the bumble-bee bat, is 2 g while that of the largest mammal, the blue whale, is 150 t or 150 million grams. Remarkably, even though they are in the same class, body size can vary up to 75-million-fold. Furthermore, this body growth can be finite in the case of most vertebrates or it can occur continuously throughout life, as for trees, molluscs and large crustaceans. Currently, we know comparatively little about the genetic control of body size. In this article we will review recent evidence from vertebrates and particularly from Drosophila that implicates insulin/insulin-like growth factor-I and other growth pathways in the control of cell, organ and body size.

Autonomous control of cell and organ size by CHICO, a Drosophila homolog of vertebrate IRS1-4

The control of growth is fundamental to the developing metazoan. Here, we show that CHICO, a Drosophila homolog of vertebrate IRS1-4, plays an essential role in the control of cell size and growth. Animals mutant for chico are less than half the size of wild-type flies, owing to fewer and smaller cells. In mosaic animals, chico homozygous cells grow slower than their heterozygous siblings, show an autonomous reduction in cell size, and form organs of reduced size. Although chico flies are smaller, they show an almost 2-fold increase in lipid levels. The similarities of the growth defects caused by mutations in chico and the insulin receptor gene in Drosophila and by perturbations of the insulin/IGF1 signaling pathway in vertebrates suggest that this pathway plays a conserved role in the regulation of overall growth by controling cell size, cell number, and metabolism.

Isomazole disposition in man as a function of dose and route of administration

The disposition of a new cardiotonic agent (isomazole (ISO] was evaluated in healthy volunteers after various single oral (p.o.), intravenous (i.v.), and multiple p.o. doses. Blood samples were collected after dosing in all studies, with urine collected in the single i.v. and multiple dose studies. All biological samples were measured for ISO. In the multiple dose study, samples were collected for analysis after the first and last doses administered. In addition to ISO, several known metabolites (hydroxyisomazole (OHISO), sulfone (SULF), and hydroxysulfone (OHSULF) analogs) were measured after the first and last doses given in the multiple dose study. Pharmacokinetic values compared between doses suggested no saturable processes existed over the entire dose range. The single i.v. dose data showed ISO experienced some extravascular distribution (mean V beta = 1.82 l kg-1), with a high clearance (mean Cls = 18.8 ml min-1 kg-1) and a short half-life (mean t 1/2 = 1.1 h). Elimination was primarily nonrenal (Clr = 3.5 ml min-1 kg-1). Single p.o. data supported these findings and further suggested rapid absorption. ISO data from the first dose of the multiple dose study was in agreement with these data; however, the last dose showed a higher Cls (33.0 ml min-1 kg-1) (p = 0.055). Although not statistically significant, metabolite plasma data and and urinary excretion patterns changed. An increase was observed in plasma AUC and metabolite excretion of SULF and OHSULF, while a decrease was observed in the same parameters for OHISO. These results suggest that multiple dosing of ISO produces autoinduction of ISO metabolism through selective metabolic routes.

14C-isomazole disposition in man after oral administration

A 50-mg dose containing 50 microCi 14C-isomazole was administered orally to five healthy male volunteers. Blood, plasma, urine, feces, and saliva were collected and measured for total 14C; in addition, all collections except feces were measured for parent drug (ISO) and three metabolites: hydroxyisomazole (OHISO) and sulfone (SULF) and hydroxysulfone (OHSULF) analogues. Urine and fecal recoveries accounted for 97.0% of the drug administered, with 62.6% excreted in urine and 32.4% in feces. Only 47% of the drug recovered in urine could be identified, with ISO the largest constituent. Total plasma 14C peaked at 1.5 hr, indicating rapid absorption, and produced a mean half-life of 3.7 hr. This was similar to the total 14C half-life found in blood (3.1 hr) but longer than in red blood cells (1.8 hr) or saliva (1.4 hr), suggesting that different ISO-related compounds contributed to the results found in each fluid or tissue. An unidentified metabolite(s) composed a large portion of circulating plasma 14C and produced the longer half-life encountered in plasma. ISO exhibited a short half-life (1.35 hr), a high oral clearance (Cls/F; 24.2 ml/min/kg), and some extravascular distribution (V beta; 3.07 L/kg). Total 14C in red blood cells and saliva related very well to plasma ISO disposition, suggesting preferential distribution of parent drug across cellular membranes. The estimated RBC:plasma ISO ratio (1.79) confirmed this hypothesis. Saliva may be used as a noninvasive means to monitor ISO disposition.

Pharmacologic effects in man of a specific serotonin-reuptake inhibitor

Fluoxetine (Li-ly 110140) caused a 63 percent inhibition of [3H]serotonin uptake into platelets obtained from normal volunteers to whom the drug was administered daily for 7 days. This dose had no effect on the usual pressor response produced by injections of norepinephrine or tyramine.