Browsing by Author "Heide, Michael"

As is evident from the theme of the Research Topic “Small Size, Big Problem: Understanding the Molecular Orchestra of Brain Development from Microcephaly,” the pathomechanisms leading to mirocephaly in human are at best partially understood. As molecular cell biologists and developmental neurobiologists, we present here a treatise with theoretical considerations that systematically dissect possible causes of microcephaly, which we believe is timely. Our considerations address the cell types affected in microcephaly, that is, the cortical stem and progenitor cells as well as the neurons and macroglial cell generated therefrom. We discuss issues such as progenitor cell types, cell lineages, modes of cell division, cell proliferation and cell survival. We support our theoretical considerations by discussing selected examples of factual cases of microcephaly, in order to point out that there is a much larger range of possible pathomechanisms leading to microcephaly in human than currently known.

The human-specific gene ARHGAP11B has been implicated in human neocortex expansion. However, the extent of ARHGAP11B's contribution to this expansion during hominid evolution is unknown. Here we address this issue by genetic manipulation of ARHGAP11B levels and function in chimpanzee and human cerebral organoids. ARHGAP11B expression in chimpanzee cerebral organoids doubles basal progenitor levels, the class of cortical progenitors with a key role in neocortex expansion. Conversely, interference with ARHGAP11B's function in human cerebral organoids decreases basal progenitors down to the chimpanzee level. Moreover, ARHGAP11A or ARHGAP11B rescue experiments in ARHGAP11A plus ARHGAP11B double-knockout human forebrain organoids indicate that lack of ARHGAP11B, but not of ARHGAP11A, decreases the abundance of basal radial glia—the basal progenitor type thought to be of particular relevance for neocortex expansion. Taken together, our findings demonstrate that ARHGAP11B is necessary and sufficient to ensure the elevated basal progenitor levels that characterize the fetal human neocortex, suggesting that this human-specific gene was a major contributor to neocortex expansion during human evolution.

The evolutionary expansion of the neocortex in the ape lineage is the basis for the development of higher cognitive abilities. However, the human brain has uniquely increased in size and degree of folding, forming an essential foundation for advanced cognitive functions. This raises the question: what factors distinguish humans from our closest living primate relatives, such as chimpanzees and bonobos, which exhibit comparatively constrained cognitive capabilities? In this review, we focus on recent studies examining (modern) human-specific genetic traits that influence neural progenitor cells, whose behavior and activity are crucial for shaping cortical morphology. We emphasize the role of human-specific genetic modifications in signaling pathways that enhance the abundance of apical and basal progenitors, as well as the importance of basal progenitor metabolism in their proliferation in human. Additionally, we discuss how changes in neuron morphology contribute to the evolution of human cognition and provide our perspective on future directions in the field.

Hyperactivity of the cysteine protease cathepsin S (CTSS) -either through Y132 mutations or amplification/overexpression- is a recurrent alteration in follicular lymphoma (FL) and promotes tumor growth by inducing a supportive immune microenvironment (Bararia et al, 2020). Of note, patients with CTSS-hyperactive FL had better outcomes with standard therapies, suggesting that CTSS-hyperactivity can sensitize tumors to treatment. CTSS hyperactivity has also been reported in other B cell lymphomas (BCLs) (Dheilly et al, 2020) and solid cancers (Olson & Joyce, 2015). CTSS is mainly localized intralysosomally but can be released into the cytosol by lysosomal membrane permeabilization (LMP). Low level LMP can occur spontaneously (e.g., during cell division) and can be enhanced by treatment. Unlike other cathepsins, cytosolically released CTSS maintains its enzymatic activity at non-acidic pH. Thus, we aimed to (i) identify the determinants of the cytosolic CTSS activity, (ii) determine its impact on the regulation of apoptosis, and (iii) study LMP as a therapeutic approach for CTSS-hyperactive tumors. First, we accrued biochemical, functional, and clinical data supporting the role of cystatin B (CSTB) as a clinically relevant endogenous CTSS inhibitor in BCLs. Through unbiased and complementary proteomics (BioID2 labelling and co-IP followed by LC-MS/MS) we identified CSTB as a direct CTSS-interacting protein (8-fold enriched in the BCL cell line Karpas422 engineered to express CTSS wild type (WT) or Y132D vs CTSS knock-out (KO), P=0.0002). Single-cell RNA-Seq of primary FL (N=10) showed significantly higher CSTB expression in FL cells compared to normal B cells ( P=0.004). Moreover, shRNA mediated knock-down (k/d) of CSTB increased the overall cathepsin activity in BCL cell lines (N=8) by 1.5 to 5.5-fold, most notably in CTSS-hyperactive cells ( Fig A, top). We next employed LMP-inducing tool compounds (LLOMe) and clinically used drugs or analogs (desipramine, hexamethylene amiloride) to release cathepsins into the cytosol. CTSS-hyperactive Karpas422 were significantly more sensitive to LMP-inducing treatments compared to native cells (1.5 to 10-fold reduction of IC50). Importantly, CTSS hyperactivity and CSTB k/d increased LMP-mediated cell killing ( Fig A, bottom). Thus, the cytosolic CTSS/CSTB interaction determines the net cytosolic cathepsin activity and sensitivity of cells to undergo LMP-induced cell death. Next, we hypothesized that LMP-induced cytosolic CTSS hyperactivity could prime BCLs towards apoptosis. We used BH3 profiling to functionally quantify the dependencies and interactions of BCL2 family members in BCLs with and without CTSS hyperactivity. In Karpas422 cells expressing CTSS Y132D, LMP increased overall apoptotic priming and dependencies on the anti-apoptotic proteins MCL-1 (delta priming >30 % at 10 µM, P=0.04), BCL-xL (>45 % at 10 µM, P=0.0006) and BCL2 (> 45 % at 0.5 and 1 µM, P=0.0001). We hypothesized that BCL2 family members are proteolytically cleaved by cytosolic CTSS. Indeed, e.g., BCL2 protein levels were 2.5 to 3.5-fold lower in LLOMe-treated Karpas422 cells with CTSS-hyperactivity compared to CTSS KO, and CSTB k/d further decreased BCL2 levels. To validate CTSS-mediated cleavage of BCL2, we purified FLAG-tagged BCL2 and CTSS WT and Y132D. CTSS WT efficiently cleaved BCL2 in vitro <1 hour at the top ranked predicted cleavage site and the reaction rate increased 1.3-fold for CTSS Y132D. Finally, we hypothesized that LMP sensitizes cells to BCL2-targeting therapies ( Fig B). The combination of LLOMe-induced LMP and the BCL2 inhibitor venetoclax (VEN) showed increased cytotoxicity in CTSS-hyperactive Karpas422 cells compared to monotherapy and CSTB k/d enhanced this phenotype ( Fig A, bottom). We assessed cathepsin activities and generated dose-response curves for VEN with and without LLOMe-induced LMP in 15 primary CLL samples. Thereof, 12 samples had intermediate or high cathepsin activities and LLOMe-induced LMP increased their sensitivity to VEN, including a VEN-resistant sample in which the IC50 decreased to <3 nM. In summary, we show that CSTB is a functionally relevant inhibitor that determines the net activity of LMP-released cytosolic CTSS. Furthermore, LMP-inducing therapies may be a promising approach to sensitize CTSS-hyperactive tumors towards apoptosis by proteolytic cleavage of BCL2 family members.

Abstract Reelin, a large extracellular protein, plays several critical roles in brain development and function. It is encoded by RELN, first identified as the gene disrupted in the reeler mouse, a classic neurological mutant exhibiting ataxia, tremors and a ‘reeling’ gait. In humans, biallelic variants in RELN have been associated with a recessive lissencephaly variant with cerebellar hypoplasia, which matches well with the homozygous mouse mutant that has abnormal cortical structure, small hippocampi and severe cerebellar hypoplasia. Despite the large size of the gene, only 11 individuals with RELN-related lissencephaly with cerebellar hypoplasia from six families have previously been reported. Heterozygous carriers in these families were briefly reported as unaffected, although putative loss-of-function variants are practically absent in the population (probability of loss of function intolerance = 1). Here we present data on seven individuals from four families with biallelic and 13 individuals from seven families with monoallelic (heterozygous) variants of RELN and frontotemporal or temporal-predominant lissencephaly variant. Some individuals with monoallelic variants have moderate frontotemporal lissencephaly, but with normal cerebellar structure and intellectual disability with severe behavioural dysfunction. However, one adult had abnormal MRI with normal intelligence and neurological profile. Thorough literature analysis supports a causal role for monoallelic RELN variants in four seemingly distinct phenotypes including frontotemporal lissencephaly, epilepsy, autism and probably schizophrenia. Notably, we observed a significantly higher proportion of loss-of-function variants in the biallelic compared to the monoallelic cohort, where the variant spectrum included missense and splice-site variants. We assessed the impact of two canonical splice-site variants observed as biallelic or monoallelic variants in individuals with moderately affected or normal cerebellum and demonstrated exon skipping causing in-frame loss of 46 or 52 amino acids in the central RELN domain. Previously reported functional studies demonstrated severe reduction in overall RELN secretion caused by heterozygous missense variants p.Cys539Arg and p.Arg3207Cys associated with lissencephaly suggesting a dominant-negative effect. We conclude that biallelic variants resulting in complete absence of RELN expression are associated with a consistent and severe phenotype that includes cerebellar hypoplasia. However, reduced expression of RELN remains sufficient to maintain nearly normal cerebellar structure. Monoallelic variants are associated with incomplete penetrance and variable expressivity even within the same family and may have dominant-negative effects. Reduced RELN secretion in heterozygous individuals affects only cortical structure whereas the cerebellum remains intact. Our data expand the spectrum of RELN-related neurodevelopmental disorders ranging from lethal brain malformations to adult phenotypes with normal brain imaging.

Abstract In this review, we focus on human‐specific features of neocortical neurogenesis in development and evolution. Two distinct topics will be addressed. In the first section, we discuss the expansion of the neocortex during human evolution and concentrate on the human‐specific gene ARHGAP11B . We review the ability of ARHGAP11B to amplify basal progenitors and to expand a primate neocortex. We discuss the contribution of ARHGAP11B to neocortex expansion during human evolution and its potential implications for neurodevelopmental disorders and brain tumors. We then review the action of ARHGAP11B in mitochondria as a regulator of basal progenitor metabolism, and how it promotes glutaminolysis and basal progenitor proliferation. Finally, we discuss the increase in cognitive performance due to the ARHGAP11B‐induced neocortical expansion. In the second section, we focus on neocortical development in modern humans versus Neanderthals. Specifically, we discuss two recent findings pointing to differences in neocortical neurogenesis between these two hominins that are due to a small number of amino acid substitutions in certain key proteins. One set of such proteins are the kinetochore‐associated proteins KIF18a and KNL1, where three modern human‐specific amino acid substitutions underlie the prolongation of metaphase during apical progenitor mitosis. This prolongation in turn is associated with an increased fidelity of chromosome segregation to the apical progenitor progeny during modern human neocortical development, with implications for the proper formation of radial units. Another such key protein is transketolase‐like 1 (TKTL1), where a single modern human‐specific amino acid substitution endows TKTL1 with the ability to amplify basal radial glia, resulting in an increase in upper‐layer neuron generation. TKTL1's ability is based on its action in the pentose phosphate pathway, resulting in increased fatty acid synthesis. The data imply greater neurogenesis during neocortical development in modern humans than Neanderthals due to TKTL1, in particular in the developing frontal lobe.

The cerebral cortex is the outermost brain structure and is responsible for the processing of sensory input and motor output; it is seen as the seat of higher-order cognitive abilities in mammals, in particular, primates. Studying gene functions in primate brains is challenging due to technical and ethical reasons, but the establishment of the brain organoid technology has enabled the study of brain development in traditional primate models (e.g., rhesus macaque and common marmoset), as well as in previously experimentally inaccessible primate species (e.g., great apes), in an ethically justifiable and less technically demanding system. Moreover, human brain organoids allow the advanced investigation of neurodevelopmental and neurological disorders. As brain organoids recapitulate many processes of brain development, they also represent a powerful tool to identify differences in, and to functionally compare, the genetic determinants underlying the brain development of various species in an evolutionary context. A great advantage of using organoids is the possibility to introduce genetic modifications, which permits the testing of gene functions. However, the introduction of such modifications is laborious and expensive. This paper describes a fast and cost-efficient approach to genetically modify cell populations within the ventricle-like structures of primate cerebral organoids, a subtype of brain organoids. This method combines a modified protocol for the reliable generation of cerebral organoids from human-, chimpanzee-, rhesus macaque-, and common marmoset-derived induced pluripotent stem cells (iPSCs) with a microinjection and electroporation approach. This provides an effective tool for the study of neurodevelopmental and evolutionary processes that can also be applied for disease modeling.

Neocortical development depends on the intrinsic ability of neural stem and progenitor cells to proliferate and differentiate to generate the different kinds of neurons in the adult brain. These progenitor cells can be distinguished into apical progenitors, which occupy a stem cell niche in the ventricular zone and basal progenitors, which occupy a stem cell niche in the subventricular zone (SVZ). During development, the stem cell niche provided in the subventricular zone enables the increased proliferation and self-renewal of basal progenitors, which likely underlie the expansion of the human neocortex. However, the components forming the SVZ stem cell niche in the developing neocortex have not yet been fully understood. In this review, we will discuss potential components of the SVZ stem cell niche, i.e., extracellular matrix composition and brain vasculature, and their possible key role in establishing and maintaining this niche during fetal neocortical development. We will also emphasize the potential role of basal progenitor morphology in maintaining their proliferative capacity within the stem cell niche of the SVZ. Finally, we will focus on the use of brain organoids to i) understand the unique features of basal progenitors, notably basal radial glia; ii) study components of the SVZ stem cell niche; and iii) provide future directions on how to improve brain organoids, notably the organoid SVZ, and make them more reliable models of human neocortical development and evolution studies.