Alternativ splicing och hur den förhåller sig till växters alternativa splicing / Alternativ splicing in animals and how it relates to the alternative splicing in plants

Gasparini, Isabella

January 2010

<p>Alternativ splicing är en process som ger upphov till att olika mRNA-sekvenser bildas från en enda gen, vilket bidrar till en ökad proteindiversitet hos organismen. Olika mRNA-sekvenser kan uppstå eftersom att det förekommer olika varianter av alternativ splicing som även kan kombineras på flera olika sätt: cassette exon (inkludering/exkludering av exon), intron retention (intronet behålls), alternative 5´splice-site choice (olika 5´ splice sites kan väljas) och slutligen alternative 3´ splice-site choice (andra 3´ splice sites kan väljas). För att alternativ splicing ska äga rum i olika pre-mRNA måste den regleras av cis-reglerande element. De cis-reglerande elementen utgörs av fyra grupper: exonic splicing enhancers (ESE), exonic splicing silencers (ESS), intronic splicing enhancers (ISE) samt intronic splicing silencers (ISS). Som namnen förtäljer finns de antingen i exoner eller introner, där de interagerar med transagerande faktorer, SR-proteiner (aktiverare) eller hnRNPs (hämmare). Alternativ splicing förekommer både i djur och i växter. Hos <em>Homo sapiens </em>genomgår över 74 % av de 25,000 gener som finns hos organismen, alternativ splicing. Däremot i växten <em>Arabidopsis thaliana</em>, genomgår endast 22 %, av den totala mängden på cirka 26,000 gener, alternativ splicing. Eftersom att processen bidrar till en ökad proteindiversitet, kommer det medföra att olika processer i organismerna påverkas, exempelvis celltillväxt, celldöd samt utvecklingen av olika sjukdomar, såsom Parkinson och cystisk fibros. Många studier har gjorts som bekräftar dess betydelse för organismerna men på grund av processens komplexitet är det fortfarande ett ämne som ständigt måste utforskas.</p><p> </p>

Alternativ splicing

spliceosom

exon

intron

splice sites

SR-proteiner

hnRNPs

NATURAL SCIENCES

NATURVETENSKAP

Alternativ splicing och hur den förhåller sig till växters alternativa splicing / Alternativ splicing in animals and how it relates to the alternative splicing in plants

Gasparini, Isabella

January 2010

Alternativ splicing är en process som ger upphov till att olika mRNA-sekvenser bildas från en enda gen, vilket bidrar till en ökad proteindiversitet hos organismen. Olika mRNA-sekvenser kan uppstå eftersom att det förekommer olika varianter av alternativ splicing som även kan kombineras på flera olika sätt: cassette exon (inkludering/exkludering av exon), intron retention (intronet behålls), alternative 5´splice-site choice (olika 5´ splice sites kan väljas) och slutligen alternative 3´ splice-site choice (andra 3´ splice sites kan väljas). För att alternativ splicing ska äga rum i olika pre-mRNA måste den regleras av cis-reglerande element. De cis-reglerande elementen utgörs av fyra grupper: exonic splicing enhancers (ESE), exonic splicing silencers (ESS), intronic splicing enhancers (ISE) samt intronic splicing silencers (ISS). Som namnen förtäljer finns de antingen i exoner eller introner, där de interagerar med transagerande faktorer, SR-proteiner (aktiverare) eller hnRNPs (hämmare). Alternativ splicing förekommer både i djur och i växter. Hos Homo sapiens genomgår över 74 % av de 25,000 gener som finns hos organismen, alternativ splicing. Däremot i växten Arabidopsis thaliana, genomgår endast 22 %, av den totala mängden på cirka 26,000 gener, alternativ splicing. Eftersom att processen bidrar till en ökad proteindiversitet, kommer det medföra att olika processer i organismerna påverkas, exempelvis celltillväxt, celldöd samt utvecklingen av olika sjukdomar, såsom Parkinson och cystisk fibros. Många studier har gjorts som bekräftar dess betydelse för organismerna men på grund av processens komplexitet är det fortfarande ett ämne som ständigt måste utforskas.

Alternativ splicing

spliceosom

exon

intron

splice sites

SR-proteiner

hnRNPs

NATURAL SCIENCES

NATURVETENSKAP

Evolutionary divergence of the heterogeneous nuclear ribonucleoproteins A/B and functional implications

Siew Ping Han

Unknown Date

The heterogeneous nuclear ribonucleoproteins (hnRNPs) are a group of proteins intitially characterised in the late 1980’s by their presence in complexes that form on nascent RNA transcripts. This definition was purely operational, and was based on protein isolation techniques available at that time. Since then, the tendency to refer to and view the hnRNPs as a protein family has become increasingly prevalent, although there has been no systematic sequence- or structure-based study of their evolutionary history. While the hnRNPs share some structural characteristics (modular structure, presence of RNA-binding domains) and functional properties (binding to RNA, involvement in multiple steps of RNA processing), these criteria also apply to other types of RNA binding proteins (RBPs), such as the SR and ELAV families of proteins. Thus, we have adopted a more methodical and rigorous approach to the classification of hnRNPs and other RBPs, through the phylogenetic analysis of their sequences and domains. Besides establishing phylogenetic relationships and simplifying nomenclature, studying the evolutionary divergence of the hnRNPs is important for understanding their functional features. The hnRNP A/B subfamily is comprised of paralogues A1, A2/B1, A3 and A0, which exhibit a high level of similarity at both the sequence and structural level. While they are often treated as functional homologues, they are not functionally identical. Hence, we undertook a detailed comparison of their sequences, and found that the introduction of novel splicing signals or mutation of existing sequence elements has led to changes in alternative splicing patterns between the paralogues, which may affect the regulation of their expression and their RNA binding properties. In addition, we also investigated species-specific alternative splicing of the hnRNPs A/B, which has significant implications for the interpretation of current research, since different research groups tend to use different model organisms in their experiments. Hence, exploration of the sequence divergence of the hnRNPs A/B has provided some clues as to how their functional differences arose, and also highlighted the need to take species-specific splicing into consideration. Alternative splicing can create functional variation not only between paralogues, but also between splice variants. hnRNP A2/B1, which has a well-established role in mRNA trafficking in neuronal cells, has four spliceoforms. In order to study the contribution of each isoform to this process, we investigated isoform-specific variations in intracellular localisation, and expression in different developmental stages and species. We found that in rat, minor isoform A2b was the predominant isoform in the cytoplasm, and may be the key player in mRNA trafficking. These findings demonstrate the importance of considering individual isoforms (including those expressed in low abundance) when studying the function of alternatively spliced proteins, especially when the function is restricted to a particular subcellular compartment. In addition to its cytoplasmic role in mRNA trafficking, hnRNP A2/B1, and the other hnRNPs A/B, have multiple nuclear functions, including packaging of nascent transcripts, nuclear export of mRNA, regulation of alternative splicing and telomere maintenance. These processes take place in discrete regions within the nucleus, and thus we examined the subnuclear distribution of the hnRNPs A/B. We found that hnRNP A1 had a localisation pattern distinct from that of A2/B1 and A3, and that these patterns were spatially and temporally regulated. Hence, the evolutionary divergence of the hnRNPs A/B has affected the localisation, expression and splicing patterns of these proteins, which we have examined at multiple levels, including comparisons across all hnRNPs, within the hnRNP A/B paralogues, and between the hnRNP A2/B1 splice variants. As the hnRNPs A/B are involved in almost every step in RNA processing, this functional diversity has significant implications for transcriptomic complexity. Furthermore, our findings highlight the importance of taking species- and isoform-specific differences into account when investigating protein function. In conclusion, this study of the hnRNPs A/B provides a conceptual framework for exploring the relationships between sequence, structural and functional divergence, which may be applicable to protein families in general.

03 Chemical Sciences

hnRNPs

phylogenetics

alternative splicing

mRNA trafficking

subnuclear localisation

Evolutionary divergence of the heterogeneous nuclear ribonucleoproteins A/B and functional implications

Siew Ping Han

Unknown Date

The heterogeneous nuclear ribonucleoproteins (hnRNPs) are a group of proteins intitially characterised in the late 1980’s by their presence in complexes that form on nascent RNA transcripts. This definition was purely operational, and was based on protein isolation techniques available at that time. Since then, the tendency to refer to and view the hnRNPs as a protein family has become increasingly prevalent, although there has been no systematic sequence- or structure-based study of their evolutionary history. While the hnRNPs share some structural characteristics (modular structure, presence of RNA-binding domains) and functional properties (binding to RNA, involvement in multiple steps of RNA processing), these criteria also apply to other types of RNA binding proteins (RBPs), such as the SR and ELAV families of proteins. Thus, we have adopted a more methodical and rigorous approach to the classification of hnRNPs and other RBPs, through the phylogenetic analysis of their sequences and domains. Besides establishing phylogenetic relationships and simplifying nomenclature, studying the evolutionary divergence of the hnRNPs is important for understanding their functional features. The hnRNP A/B subfamily is comprised of paralogues A1, A2/B1, A3 and A0, which exhibit a high level of similarity at both the sequence and structural level. While they are often treated as functional homologues, they are not functionally identical. Hence, we undertook a detailed comparison of their sequences, and found that the introduction of novel splicing signals or mutation of existing sequence elements has led to changes in alternative splicing patterns between the paralogues, which may affect the regulation of their expression and their RNA binding properties. In addition, we also investigated species-specific alternative splicing of the hnRNPs A/B, which has significant implications for the interpretation of current research, since different research groups tend to use different model organisms in their experiments. Hence, exploration of the sequence divergence of the hnRNPs A/B has provided some clues as to how their functional differences arose, and also highlighted the need to take species-specific splicing into consideration. Alternative splicing can create functional variation not only between paralogues, but also between splice variants. hnRNP A2/B1, which has a well-established role in mRNA trafficking in neuronal cells, has four spliceoforms. In order to study the contribution of each isoform to this process, we investigated isoform-specific variations in intracellular localisation, and expression in different developmental stages and species. We found that in rat, minor isoform A2b was the predominant isoform in the cytoplasm, and may be the key player in mRNA trafficking. These findings demonstrate the importance of considering individual isoforms (including those expressed in low abundance) when studying the function of alternatively spliced proteins, especially when the function is restricted to a particular subcellular compartment. In addition to its cytoplasmic role in mRNA trafficking, hnRNP A2/B1, and the other hnRNPs A/B, have multiple nuclear functions, including packaging of nascent transcripts, nuclear export of mRNA, regulation of alternative splicing and telomere maintenance. These processes take place in discrete regions within the nucleus, and thus we examined the subnuclear distribution of the hnRNPs A/B. We found that hnRNP A1 had a localisation pattern distinct from that of A2/B1 and A3, and that these patterns were spatially and temporally regulated. Hence, the evolutionary divergence of the hnRNPs A/B has affected the localisation, expression and splicing patterns of these proteins, which we have examined at multiple levels, including comparisons across all hnRNPs, within the hnRNP A/B paralogues, and between the hnRNP A2/B1 splice variants. As the hnRNPs A/B are involved in almost every step in RNA processing, this functional diversity has significant implications for transcriptomic complexity. Furthermore, our findings highlight the importance of taking species- and isoform-specific differences into account when investigating protein function. In conclusion, this study of the hnRNPs A/B provides a conceptual framework for exploring the relationships between sequence, structural and functional divergence, which may be applicable to protein families in general.

03 Chemical Sciences

hnRNPs

phylogenetics

alternative splicing

mRNA trafficking

subnuclear localisation