What is Chimeric RNA?

Chimeric RNA, also known as fusion RNA, refers to RNA molecules that are formed as a result of the fusion of two or more different RNA transcripts. Chimeric RNA, a unique class of RNA molecules formed through various molecular mechanisms, such as trans-splicing, read-through transcription, and fusion genes. These hybrid transcripts play a significant role in diverse biological processes and have gained substantial attention in recent years.

Chimeric RNA Formation

Like mentioned earlier, the formation of chimeric RNAs involves multiple mechanisms. Chimeric RNA refers to a type of RNA molecule that is formed by the fusion of genetic material from two or more distinct genes. These chimeras can arise through different mechanisms, including chromosomal translocation, cis-splicing, or trans-splicing.

• Trans-splicing occurs when exons from different genes are spliced together, generating novel RNA molecules. Read-through transcription refers to the transcriptional read-through of adjacent genes, leading to the production of fusion transcripts. Fusion genes, resulting from chromosomal rearrangements, create chimeric RNA molecules by merging portions of two separate genes. These mechanisms give rise to unique transcripts that can have functional implications, such as altered protein-coding potential, regulatory effects, or generation of novel biomarkers.
• In chromosomal translocation, portions of two separate chromosomes break and rejoin, resulting in the fusion of two different genes. This rearrangement can occur within a single cell, leading to the production of chimeric RNA molecules.
• Cis splicing involves the abnormal joining of exons from two different genes located on the same chromosome. This can occur due to genetic mutations or errors in the splicing process. Trans-splicing, on the other hand, involves the joining of exons from different genes that are located on different chromosomes. This process requires the action of special trans-splicing machinery.

Chimeric RNAs have been observed in various organisms, including humans, and have been found to play a role in a variety of diseases, particularly cancer. They can contribute to tumorigenesis by generating abnormal proteins or disrupting normal cellular processes. Chimeric RNAs have also been implicated in other diseases, such as neurological disorders.

Sequencing Technologies for Chimeric RNA Detection

Chimeric RNA molecules, which arise from genomic rearrangements, alternative splicing, or fusion events, have emerged as crucial players in diverse biological processes and disease pathogenesis. Traditional sequencing methods, and next-generation sequencing (NGS) technologies as well as emerging long-read sequencing platforms, have traditionally been employed for chimeric RNA detection.

• Traditional sequencing methods, like Sanger sequencing and reverse transcription PCR (RT-PCR), have been historically employed for chimeric RNA detection. However, these techniques are limited in their ability to detect and characterize complex chimeric events and lack scalability.
• Next-generation sequencing technologies, particularly RNA-seq, have revolutionized chimeric RNA research. RNA-seq enables the high-throughput sequencing of transcriptomes, facilitating the discovery of novel chimeric events. It can efficiently identify multiple chimeric transcripts and DNA structural variants, especially when coupled with long RNA-seq reads and true chimeric mRNAs. RNA-seq provides valuable insights into transcriptome complexity and offers opportunities to study alternative splicing events and isoform diversity. Additionally, single-cell RNA-seq techniques enable the detection and analysis of chimeric RNA at the single-cell level, uncovering insights into cellular heterogeneity and disease processes.
• Emerging sequencing technologies, such as nanopore sequencing and PacBio sequencing, offer long-read sequencing capabilities. These technologies can provide valuable information about full-length chimeric transcripts, uncovering complex structural variations and alternative splicing events. But they have their own advantages and features. Nanopore sequencing offers the advantage of producing long reads, which are essential for capturing full-length chimeric transcripts, which provide information on the sequence and structural characteristics of chimeric RNA molecules, including complex structural variations and alternative splicing events. Furthermore, it enables the detection of base modifications and RNA modifications, contributing to the understanding of post-transcriptional RNA processing. PacBio sequencing, also known as Single Molecule, Real-Time (SMRT) sequencing, represents another long-read sequencing technology that holds promise for chimeric RNA analysis. This technology employs circular consensus sequencing (CCS) to generate highly accurate long reads. It offers high-resolution insights into RNA molecules and facilitates the investigation of intricate transcriptome landscapes.

Computational Analysis of Chimeric RNA Data

Chimeric RNA data analysis necessitates a multifaceted computational framework to unravel the intricacies inherent in these composite transcripts.

In general, analyzing chimeric RNA data involves several computational steps:

A.     Preprocessing and quality control. Preprocessing chimeric RNA data mandates meticulous artifact filtering and curation of low-quality reads to ensure the integrity and reliability of subsequent analyses. By applying sophisticated techniques, such as noise reduction algorithms, sequence trimming, and adapter removal, spurious artifacts are mitigated, fostering robust downstream analysis.

B.      Alignment and mapping. The alignment and mapping phase entails the meticulous alignment of sequencing reads to reference genomes or transcriptomes, thereby enabling the discernment of chimeric RNA junctions. This process necessitates the utilization of sophisticated alignment algorithms, including splice-aware aligners or de novo assembly methods, to accurately identify and characterize these fusion events.

C.      Identification and quantification of chimeric RNA. It necessitates the deployment of specialized algorithms capable of deciphering the presence and relative abundance of chimeric transcripts. Advanced techniques, such as fusion gene detection algorithms, breakpoint analysis, or statistical modeling approaches, empower researchers to discern intricate patterns and uncover novel chimeric events lurking within the dataset.

 D. Visualization and interpretation. Complex chimeric RNA structures present an intellectual challenge that demands state-of-the-art visualization and interpretation tools. These tools facilitate the comprehension of intricate chimeric RNA arrangements by offering visual representations, such as circular plots, heatmaps, or interactive networks. Integration with complementary datasets, such as gene expression profiles or functional annotations, enriches the interpretative capacity, unraveling potential functional roles and underlying mechanisms of chimeric RNA molecules.

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What Are fungi?

Fungi can be single-celled or multicellular organisms. They are present in almost any habitat, but most live on the ground, instead of in the sea or freshwater, mostly in soil or plant material. In soil or on decaying plants, a community called the decomposers develops where they play a significant role in the recycling of carbon and other elements. Some are disease-causing plant pests such as mildews, rusts, scabs, or canker. Fungal illness in plants can contribute to severe monetary losses for farmers. In mammals, a relatively limited number of fungi causes illnesses. They include skin disorders such as foot, ringworm, and thrush in humans.

General Parts of Fungi

Fungi, unlike any other organism, are special species with body configurations and reproductive modes. The mycelium which is made up of hyphae, the fruiting body, and the spores are the main characteristics of a fungal body. Some fungi appear like trees, however, like mammals, fungi are heterotrophs. A fungus must digest food in order to survive, whereas plants are autotrophs that, by photosynthesis, make their own food.

Mycelium

A fungal mycelium is a network of filaments called hyphae that are threadlike. The mycelium gains nutrients and creates the fruiting body (usually from rotting organic matter). Most of the mycelium will always remain underground.

Fruiting Body

The reproductive framework is the fruiting body of a fungus. A mushroom, connected to a mycelium underground, is a standard fungal fruiting body. Spores are formed by a fruiting organism.

Spores

Fungal replication requires spores. Fungal spores produced by the fruiting body are haploid, indicating they only bear one chromosome for each gene (like human gametes). When they strike moist soil, spores will germinate.

Life Cycle of fungi

Reproduction

Fungi replicate sexually and/or asexually. Perfect fungi are sexually and asexually replicated, whereas imperfect fungi are only asexually reproduced (by mitosis). In both sexual and asexual reproduction, fungi develop spores that either fly on the wind or take a ride on an animal, dispersing from the parent organism. Fungal spores are thinner than plant seeds and are lighter. Bursting free, the massive puffball mushroom sheds trillions of spores. The enormous number of spores released increases the chance of landing in an atmosphere that will encourage growth.

Asexual Reproduction

By division, flowering, or developing spores, fungi replicate asexually. Hyphae fragments can allow new colonies to emerge. Mycelial separation happens when a fungal mycelium, with each part expanding into a different mycelium, splits into parts. Somatic cells form buds in yeast. A bulge forms on the side of the cell during budding (a type of cytokinesis), the nucleus separates mitotically, and the bud eventually detaches itself from the mother cell.

The most common mode of asexual reproduction is the development of asexual spores, formed only by one parent (through mitosis) and genetically identical to that parent. Spores make it possible for fungi to extend their spread and colonize new habitats. They may be produced either outside or inside a special reproductive sac called a sporangium from the parent thallus.

Sexual Reproduction

Genetic diversity is incorporated into a community of fungi through sexual reproduction. In fungi, in response to unfavorable environmental circumstances, sexual reproduction also occurs. Two kinds of mating are produced. It is called homothallic, or self-fertile, when all mating forms are found in the same mycelium. To replicate sexually, heterothallic mycelia need two separates, but compatible, mycelia.

While fungal sexual reproduction has several variants, all of them have the following three stages. First, two haploid cells merge through plasmogamy (literally, ‘cytoplasm marriage or union’), progressing to a dikaryotic stage where two haploid nuclei exist side by side in a single cell. The haploid nuclei react to form a diploid zygote nucleus during karyogamy (“nuclear marriage”). Finally, meiosis occurs in the organs of the gametangia (singular, gametangium) in which gametes of various forms of mating are produced. Spores are distributed into the atmosphere at this point.

Sequencing for Fungal Research

The fungi world is a colorful world with a lot of mysteries yet to be uncovered. Fungi ITS sequencing and fungal whole-genome sequencing are two of the main technologies used in modern mycology studies. By sequencing the targeted genome area or the complete genome, these two methods help scientists explore the fungal community, discovering strains of industrial interest, curing diseases, developing biotechnological tools, and more.

CD Genomics is a genomics service company with a good reputation in providing reliable sequencing, genotyping, microarray, and bioinformatics services. Our fungal sequencing solutions vary from taxonomic profiling to discovering complex metabolic pathways to identifying metabolites that are beneficial to human health and more. Our platform provides data on the fungal genome sequence, helping to improve medical science, agriculture science, ecology, bioremediation, bioenergy, and biotech industries.

References

1. Nilsson RH, Anslan S, Bahram M, et al. Mycobiome diversity: high-throughput sequencing and identification of fungi. Nature Reviews Microbiology. 2019, 17(2).
2. Lull C, Wichers HJ, Savelkoul HF. Antiinflammatory and immunomodulating properties of fungal metabolites. Mediators of inflammation. 2005(2).

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