AMFR dysfunction causes autosomal recessive spastic paraplegia in human that is amenable to statin treatment in a preclinical model

Primary disorders of polyubiquitination: Dual roles in autoinflammation and immunodeficiency

The last decades have brought a rapid expansion of the number of primary disorders related to the polyubiquitination pathways in humans. Most of these disorders manifest with two seemingly contradictory clinical phenotypes: autoinflammation, immunodeficiency, or both. We provide an overview of the molecular pathogenesis of these disorders, and their role in inflammation and infection. By focusing on data from human genetic diseases, we explore the complexities of the polyubiquitination pathways and the corresponding clinical phenotypes of their deficiencies. We offer a road map for the discovery of new genetic etiologies. By considering the triggers that induce inflammation, we propose autoinflammation and immunodeficiency as continuous clinical phenotypes.

The autocrine motility factor receptor delays the pathological progression of Alzheimer's disease via regulating the ubiquitination-mediated degradation of APP

BACKGROUND

The ubiquitin-proteasome system (UPS) is responsible for most protein degradation and its malfunction is normally observed in neurodegenerative diseases, including Alzheimer's disease (AD). The autocrine motility factor receptor (AMFR) is an E3 ubiquitin ligase that resides on the endoplasmic reticulum membrane and is involved in various essential biological processes. However, the role of AMFR in AD is still unidentified.

METHODS

Behavioral experiments, including open-field test (OFT), novel object recognition test (NORT) and morris water maze test (MWMT) were conducted after adeno-associated virus (AAV) microinjection into AD model mice. Western blot, co-immunoprecipitation (Co-IP), qPCR and ubiquitination assay were used to analyze AMFR mediated ubiquitination degradation of amyloid precursor protein (APP). ELISA was employed to evaluate changes in amyloidogenic cleavage products of APP following upregulation or downregulation of AMFR in neural cells and analyze AMFR levels in serum and cerebrospinal fluid (CSF) of AD patients.

RESULTS

The progressive decline in AMFR levels was found not only in the hippocampus of APPswe/PSEN1dE9 (APP/PS1) mice but also in the CSF and serum of patients with AD. Moreover, the interaction of AMFR and APP was observed both in hippocampal tissues and brain neurons. In addition, AMFR promoted the K11-linked polyubiquitination of APP to speed up its proteasomal degradation, resulting in decreased Aβ production. Importantly, AMFR overexpression largely rescued the cognitive and synaptic deficits in APP/PS1 mice.

CONCLUSIONS

Taken together, our results demonstrated that AMFR reduced Aβ production and alleviated cognitive impairment by promoting the ubiquitination-mediated degradation of APP. This study indicated that AMFR could have the potential to be a therapeutic target of early-stage AD.

A Novel Loss of Function Variant in HCN1 Gene Underlies Early Infantile Epileptic Encephalopathy 24 [EIEE24]

Background

Early infantile epileptic encephalopathy (EIEE) is a rare neurological condition characterized by frequent seizures in the early stages of life, resulting in severely impaired cognitive and motor development. Although the specific causes of EIEE remain unknown, one of the primary causes is gene pathogenicity (even in the absence of consanguinity). Hyperpolarization-activated cyclic nucleotide-gated channels (HCNs) are essential for proper brain function. They are regulated by multiple genes, and mutations in these genes induce channel malfunction, which can result in various severe conditions, including EIEE. Herein, we have reported a patient presenting hallmarks of EIEE.

Methods

The patient underwent clinical, radiographic, and genetic analysis. A thorough clinical examination and molecular study were conducted utilizing whole exome sequencing and Sanger sequencing.

Results

Whole exome sequencing of the proband revealed a novel de novo nonsynonymous/nonsense variant (c.1468A>T; (p.Lys490Ter) in exon 6 of the HCN1 gene. This variant may cause channel dysfunction via nonsynonymous/nonsense-mediated decay or aberrant protein, which may be associated with EIEE phenotypes.

Conclusions

This evidence backs the idea that HCN1 has a vital role in brain development and lose of function can cause a range of debilitating conditions. Still, the functional characterization study of the HCN1 variants will be the fundamental tool for a better understanding of EIEE in the near future.

BRCC3 -Associated Syndromic Moyamoya Angiopathy Diagnosed Through Clinical RNA Sequencing

Moyamoya angiopathy is a cerebral vasculopathy causing progressive stenosis of the internal carotid arteries and the compensatory development of collateral blood vessels, leading to brain ischemia and an increased risk of cerebral haemorrhage. Although multiple non-genetic causes have been associated with moyamoya syndrome, it can also be associated with rare genetic syndromes. Moyamoya Disease 4, characterised by a short stature, hypergonadotropic hypogonadism and facial dysmorphism (MYMY4, OMIM #300845), also referred to as BRCC3-associated moyamoya syndrome, has so far been described in 11 individuals. Here, we describe a 23-year-old male presenting with moyamoya syndrome, global developmental delay and intellectual disability, epilepsy, short stature and dysmorphic features, who after > 17 years of uninformative diagnostics was diagnosed with BRCC3-associated moyamoya syndrome after clinical RNA-seq. Transcriptome analysis showed reduced expression of the likely disease-causing gene BRCC3 in patient-derived fibroblasts, which was subsequently found to be caused by a ~ 26 kb Xq28 deletion. We furthermore review all reported cases of BRCC3-associated moyamoya syndrome, further delineating this clinical entity.

Endoplasmic reticulum (ER) protein degradation by ER-associated degradation and ER-phagy

Protein misfolding and aggregation in the endoplasmic reticulum (ER) have been causally linked to a variety of human diseases. Two key pathways for eliminating misfolded proteins and aggregates in the ER are ER-associated degradation (ERAD) and ER-phagy, respectively. While both pathways have been well characterized biochemically, our understanding of their physiological relevance and significance remains limited. In recent years, significant advances have been made, including the generation and characterization of various knockout and knockin mouse models, the identification of human disease-associated or -causing variants, and insights into the coordination between ERAD and autophagy in physiological contexts. In this review, we summarize these advancements, highlighting the key roles of a highly conserved suppressor of lin-12-like-hydroxymethyl glutaryl-coenzyme A reductase degradation 1 (SEL1L-HRD1) protein complex of ERAD and ER-phagy in health and disease.

Biallelic variants in SREBF2 cause autosomal recessive spastic paraplegia

Hereditary spastic paraplegias (HSPs) refer to a genetically and clinically heterogeneous group of neurodegenerative disorders characterized by the degeneration of motor neurons. To date, a significant number of patients still have not received a definite genetic diagnosis. Therefore, identifying unreported causative genes continues to be of great importance. Here, we perform whole exome sequencing in a cohort of Chinese HSP patients. Three homozygous variants (p.L604W, p.S517F, and p.T984A) within the sterol regulatory element-binding factor 2 (SREBF2) gene are identified in one autosomal recessive family and two sporadic patients, respectively. Co-segregation is confirmed by Sanger sequencing in all available members. The three variants are rare in the public or in-house database and are predicted to be damaging. The biological impacts of variants in SREBF2 are examined by functional experiments in patient-derived fibroblasts and Drosophila. We find that the variants upregulate cellular cholesterol due to the overactivation of SREBP2, eventually impairing the autophagosomal and lysosomal functions. The overexpression of the mature form of SREBP2 leads to locomotion defects in Drosophila. Our findings identify SREBF2 as a causative gene for HSP and highlight the impairment of cholesterol as a critical pathway for HSP.

Re-analysis of whole genome sequencing ends a diagnostic odyssey: Case report of an RNU4-2 related neurodevelopmental disorder

Despite increasing knowledge of disease-causing genes in human genetics, approximately half of the individuals affected by neurodevelopmental disorders remain genetically undiagnosed. Part of this missing heritability might be caused by genetic variants outside of protein-coding genes, which are not routinely diagnostically investigated. A recent preprint identified de novo variants in the non-coding spliceosomal snRNA gene RNU4-2 as a cause of a frequent novel syndromic neurodevelopmental disorder. Here we mined 164 whole genome sequencing (WGS) trios from individuals with neurodevelopmental or multiple congenital anomaly disorders that received diagnostic genomic investigations at our clinic. We identify a recurrent de novo RNU4-2 variant (NR_003137.2(RNU4-2):n.64_65insT) in a 5-year-old girl with severe global developmental delay, hypotonia, microcephaly, and seizures that likely explains her phenotype, given that extensive previous genetic investigations failed to identify an alternative cause. We present detailed phenotyping of the individual obtained during a 5-year follow-up. This includes photographs showing recognizable facial features for this novel disorder, which might allow prioritizing other currently unexplained affected individuals sharing similar facial features for targeted investigations of RNU4-2. This case illustrates the power of re-analysis to solve previously unexplained cases even when a diagnostic genome remains negative.

Experimental Cell Models for Investigating Neurodegenerative Diseases

Experimental models play a pivotal role in biomedical research, facilitating the understanding of disease mechanisms and the development of novel therapeutics. This is particularly true for neurodegenerative diseases, such as Alzheimer's disease, Parkinson's disease, Huntington's disease, amyotrophic lateral sclerosis, and motor neuron disease, which present complex challenges for research and therapy development. In this work, we review the recent literature about experimental models and motor neuron disease. We identified three main categories of models that are highly studied by scientists. In fact, experimental models for investigating these diseases encompass a variety of approaches, including modeling the patient's cell culture, patient-derived induced pluripotent stem cells, and organoids. Each model offers unique advantages and limitations, providing researchers with a range of tools to address complex biological questions. Here, we discuss the characteristics, applications, and recent advancements in terms of each model system, highlighting their contributions to advancing biomedical knowledge and translational research.

Identification and analyses of exonic and copy number variants in spastic paraplegia

Hereditary spastic paraplegias are a diverse group of degenerative disorders that are clinically categorized as isolated; with involvement of lower limb spasticity, or symptomatic, where spastic paraplegia is complicated by further neurological features. We sought to identify the underlying genetic causes of these disorders in the participating patients. Three consanguineous families with multiple affected members were identified by visiting special schools in the Punjab Province. DNA was extracted from blood samples of the participants. Exome sequencing was performed for selected patients from the three families, and the data were filtered to identify rare homozygous variants. ExomeDepth was used for the delineation of the copy number variants. All patients had varying degrees of intellectual disabilities, poor speech development, spasticity, a wide-based gait or an inability to walk and hypertonia. In family RDHR07, a homozygous deletion involving multiple exons and introns of SPG11 (NC000015.9:g.44894055_449028del) was found and correlated with the phenotype of the patients who had spasticity and other complex movement disorders, but not those who exhibited ataxic or indeterminate symptoms as well. In families ANMD03 and RDFA06, a nonsense variant, c.985C > T;(p.Arg329Ter) in DDHD2 and a frameshift insertion‒deletion variant of AP4B1, c.965-967delACTinsC;p.(Tyr322SerfsTer14), were identified which were homozygous in the patients while the obligate carriers in the respective pedigrees were heterozygous. All variants were ultra-rare with none, or very few carriers identified in the public databases. The three loss of function variants are likely to cause nonsense-mediated decay of the respective transcripts. Our research adds to the genetic variability associated with the SPG11 and AP4B1 variants and emphasizes the genetic heterogeneity of hereditary spastic paraplegia.

Diving deep: zebrafish models in motor neuron degeneration research

In the dynamic landscape of biomedical science, the pursuit of effective treatments for motor neuron disorders like hereditary spastic paraplegia (HSP), amyotrophic lateral sclerosis (ALS), and spinal muscular atrophy (SMA) remains a key priority. Central to this endeavor is the development of robust animal models, with the zebrafish emerging as a prime candidate. Exhibiting embryonic transparency, a swift life cycle, and significant genetic and neuroanatomical congruencies with humans, zebrafish offer substantial potential for research. Despite the difference in locomotion-zebrafish undulate while humans use limbs, the zebrafish presents relevant phenotypic parallels to human motor control disorders, providing valuable insights into neurodegenerative diseases. This review explores the zebrafish's inherent traits and how they facilitate profound insights into the complex behavioral and cellular phenotypes associated with these disorders. Furthermore, we examine recent advancements in high-throughput drug screening using the zebrafish model, a promising avenue for identifying therapeutically potent compounds.

Confirmation and expansion of the phenotype of the TCEAL1-related neurodevelopmental disorder

Numerous contiguous gene deletion syndromes causing neurodevelopmental disorders have previously been defined using cytogenetics for which only in the current genomic era the disease-causing genes have become elucidated. One such example is deletion at Xq22.2, previously associated with a neurodevelopmental disorder which has more recently been found to be caused by de novo loss-of-function variants in TCEAL1. So far, a single study reported six unrelated individuals with this monogenetic disorder, presenting with syndromic features including developmental delay especially affecting expressive speech, intellectual disability, autistic-like behaviors, hypotonia, gait abnormalities and mild facial dysmorphism, in addition to ocular, gastrointestinal, and immunologic abnormalities. Here we report on four previously undescribed individuals, including two adults, with de novo truncating variants in TCEAL1, identified through trio exome or genome sequencing, further delineating the phenotype of the TCEAL1-related disorder. Whereas overall we identify similar features compared to the original report, we also highlight features in our adult individuals including hyperphagia, obesity, and endocrine abnormalities including hyperinsulinemia, hyperandrogenemia, and polycystic ovarian syndrome. X chromosome inactivation and RNA-seq studies further provide functional insights in the molecular mechanisms. Together this report expands the phenotypic and molecular spectrum of the TCEAL1-related disorder which will be useful for counseling of newly identified individuals and their families.