Envisioning the development of a CRISPR-Cas mediated base editing strategy for a patient with a novel pathogenic CRB1 single nucleotide variant.

BACKGROUND: Inherited retinal degeneration (IRD) associated with mutations in the Crumbs homolog 1 (CRB1) gene is associated with a severe, early-onset retinal degeneration for which no therapy currently exists. Base editing, with its capability to precisely catalyse permanent nucleobase conversion in a programmable manner, represents a novel therapeutic approach to targeting this autosomal recessive IRD, for which a gene supplementation is challenging due to the need to target three different retinal CRB1 isoforms. PURPOSE: To report and classify a novel CRB1 variant and envision a possible therapeutic approach in form of base editing. METHODS: Case report. RESULTS: A 16-year-old male patient with a clinical diagnosis of early-onset retinitis pigmentosa (RP) and characteristic clinical findings of retinal thickening and coarse lamination was seen at the Oxford Eye Hospital. He was found to be compound heterozygous for two CRB1 variants: a novel pathogenic nonsense variant in exon 9, c.2885T>A (p.Leu962Ter), and a likely pathogenic missense change in exon 6, c.2056C>T (p.Arg686Cys). While a base editing strategy for c.2885T>A would encompass a CRISPR-pass mediated "read-through" of the premature stop codon, the resulting missense changes were predicted to be "possibly damaging" in in-silico analysis. On the other hand, the transversion missense change, c.2056C>T, is amenable to transition editing with an adenine base editor (ABE) fused to a SaCas9-KKH with a negligible chance of bystander edits due to an absence of additional Adenines (As) in the editing window. CONCLUSIONS: This case report records a novel pathogenic nonsense variant in CRB1 and gives an example of thinking about a base editing strategy for a patient compound heterozygous for CRB1 variants.

Studies on hybrid comoviruses reveal the importance of three-dimensional structure for processing of the viral coat proteins and show that the specificity of cleavage is greater in trans than in cis.

A series of cowpea mosaic virus (CPMV)-based hybrid comoviral RNA-2 molecules have been constructed. In these, the region encoding both the large (L) and small (S) viral coat proteins was replaced by the equivalent region from bean pod mottle virus (BPMV). The hybrid RNA-2 molecules were able to replicate in cowpea protoplasts in the presence of CPMV RNA-1. Though processing of the hybrid polyproteins by the CPMV-specific 24K proteinase at the site between the 58/48K and L proteins could readily be achieved, no processing at the site between the L and S coat proteins could be obtained even when the sequence of amino acids between the two coat proteins was made CPMV-like. As a result, none of the hybrids was able to form functional virus particles, and they could not infect cowpea plants. Comparison with the processing of the L-S site in cis in reticulocyte lysates demonstrated that the requirements for processing are more stringent in trans than in cis. The results suggest that the L-S cleavage site is defined by more than just a linear sequence of amino acids and probably involves interactions between the L-S loop and the beta barrels of the viral coat proteins.

The nucleotide sequence of red clover mottle virus bottom component RNA.

The complete nucleotide sequence of the bottom component RNA (B RNA) of red clover mottle virus strain S has been determined. The sequence consists of 6033 nucleotides and contains a single long open reading frame sufficient to encode a protein of M(r) 210,258. The proteolytic processing sites within this protein have been deduced by comparison of its sequence with that of the B RNA-encoded protein of cowpea mosaic virus. Comparison of the amino acid sequences of the individual proteins confirms that the two viruses have a similar genome organization.

Analysis of the nucleotide sequence of bean pod mottle virus middle component RNA.

The complete nucleotide sequence of the middle component RNA (M RNA) of the comovirus bean pod mottle virus (BPMV) has been determined. The sequence consists of 3662 nucleotides and contains a single long open reading frame sufficient to code for a protein of 113,353 Da. The proteolytic processing sites within this protein have been identified by comparison with the known three-dimensional structure of the virion and cleavage at these sites would lead to a range of products consistent with those observed during processing of the M RNA-encoded polyproteins in vitro. We have performed computer-aided searches for reiterated sequences within BPMV M RNA which might explain why ordered RNA is visible in the electron density map of BPMV middle component particles (Chen, Z., Stauffacher, C. V., Li, Y., Schmidt, T., Bomu, W., Kamer, G., Shanks, M., Lomonossoff, G., and Johnson, J. E., 1989, Science 245, 154-159). These searches revealed both the presence of overrepresented pentameric sequences and a consensus sequence which was repeated 15 times within the RNA sequence.

An electron microscopic study of the termination of thalamocortical fibres in areas 3b, 1 and 2 of the somatic sensory cortex in the monkey.

The degeneration of the terminals of thalamocortical fibres has been studied in areas 2b, 1 and 2 of the first somatic sensory area of the monkey 4 and 5 days after large electrolytic lesions in the ventral posterior nucleus of the thalamus. The number of degenerating terminals is much greater and the rate of their degeneration faster in area 3b than in areas 1 and 2, and in all areas they are concentrated in a band occupying the deep part of layer III and the upper half of layer IV. Two examples of dendrodendritic synapses were found in the deep part of the somatic sensory cortex, one in area 3b and the other in area 1.