TopFIND 4.0

Q9UMR2: ATP-dependent RNA helicase DDX19B

General Information

Protein names
- ATP-dependent RNA helicase DDX19B
- 3.6.4.13
- DEAD box RNA helicase DEAD5
- DEAD box protein 19B

Gene names DDX19B
Organism Homo sapiens
Protease Family
Protease ID
Chromosome location
UniProt ID Q9UMR2

9

N-termini

1

C-termini

0

Cleavages

0

Substrates

Sequence

        10         20         30         40         50         60 
MATDSWALAV DEQEAAAESL SNLHLKEEKI KPDTNGAVVK TNANAEKTDE EEKEDRAAQS 
        70         80         90        100        110        120 
LLNKLIRSNL VDNTNQVEVL QRDPNSPLYS VKSFEELRLK PQLLQGVYAM GFNRPSKIQE 
       130        140        150        160        170        180 
NALPLMLAEP PQNLIAQSQS GTGKTAAFVL AMLSQVEPAN KYPQCLCLSP TYELALQTGK 
       190        200        210        220        230        240 
VIEQMGKFYP ELKLAYAVRG NKLERGQKIS EQIVIGTPGT VLDWCSKLKF IDPKKIKVFV 
       250        260        270        280        290        300 
LDEADVMIAT QGHQDQSIRI QRMLPRNCQM LLFSATFEDS VWKFAQKVVP DPNVIKLKRE 
       310        320        330        340        350        360 
EETLDTIKQY YVLCSSRDEK FQALCNLYGA ITIAQAMIFC HTRKTASWLA AELSKEGHQV 
       370        380        390        400        410        420 
ALLSGEMMVE QRAAVIERFR EGKEKVLVTT NVCARGIDVE QVSVVINFDL PVDKDGNPDN 
       430        440        450        460        470    
ETYLHRIGRT GRFGKRGLAV NMVDSKHSMN ILNRIQEHFN KKIERLDTDD LDEIEKIAN

Isoforms

- Isoform 2 of ATP-dependent RNA helicase DDX19B - Isoform 3 of ATP-dependent RNA helicase DDX19B - Isoform 4 of ATP-dependent RNA helicase DDX19B - Isoform 3 of ATP-dependent RNA helicase DDX19B - Isoform 4 of ATP-dependent RNA helicase DDX19B

Sequence View

        10         20         30         40         50         60 
MATDSWALAV DEQEAAAESL SNLHLKEEKI KPDTNGAVVK TNANAEKTDE EEKEDRAAQS 
        70         80         90        100        110        120 
LLNKLIRSNL VDNTNQVEVL QRDPNSPLYS VKSFEELRLK PQLLQGVYAM GFNRPSKIQE 
       130        140        150        160        170        180 
NALPLMLAEP PQNLIAQSQS GTGKTAAFVL AMLSQVEPAN KYPQCLCLSP TYELALQTGK 
       190        200        210        220        230        240 
VIEQMGKFYP ELKLAYAVRG NKLERGQKIS EQIVIGTPGT VLDWCSKLKF IDPKKIKVFV 
       250        260        270        280        290        300 
LDEADVMIAT QGHQDQSIRI QRMLPRNCQM LLFSATFEDS VWKFAQKVVP DPNVIKLKRE 
       310        320        330        340        350        360 
EETLDTIKQY YVLCSSRDEK FQALCNLYGA ITIAQAMIFC HTRKTASWLA AELSKEGHQV 
       370        380        390        400        410        420 
ALLSGEMMVE QRAAVIERFR EGKEKVLVTT NVCARGIDVE QVSVVINFDL PVDKDGNPDN 
       430        440        450        460        470    
ETYLHRIGRT GRFGKRGLAV NMVDSKHSMN ILNRIQEHFN KKIERLDTDD LDEIEKIAN         10         20         30         40         50         60 
MATDSWALAV DEQEAAAESL SNLHLKEEKI KPDTNGAVVK TNANAEKTDE EEKEDRAAQS 
        70         80         90        100        110        120 
LLNKLIRSNL VDNTNQVEVL QRDPNSPLYS VKSFEELRLK PQLLQGVYAM GFNRPSKIQE 
       130        140        150        160        170        180 
NALPLMLAEP PQNLIAQSQS GTGKTAAFVL AMLSQVEPAN KYPQCLCLSP TYELALQTGK 
       190        200        210        220        230        240 
VIEQMGKFYP ELKLAYAVRG NKLERGQKIS EQIVIGTPGT VLDWCSKLKF IDPKKIKVFV 
       250        260        270        280        290        300 
LDEADVMIAT QGHQDQSIRI QRMLPRNCQM LLFSATFEDS VWKFAQKVVP DPNVIKLKRE 
       310        320        330        340        350        360 
EETLDTIKQY YVLCSSRDEK FQALCNLYGA ITIAQAMIFC HTRKTASWLA AELSKEGHQV 
       370        380        390        400        410        420 
ALLSGEMMVE QRAAVIERFR EGKEKVLVTT NVCARGIDVE QVSVVINFDL PVDKDGNPDN 
       430        440        450        460        470    
ETYLHRIGRT GRFGKRGLAV NMVDSKHSMN ILNRIQEHFN KKIERLDTDD LDEIEKIAN         10         20         30         40         50         60 
MATDSWALAV DEQEAAAESL SNLHLKEEKI KPDTNGAVVK TNANAEKTDE EEKEDRAAQS 
        70         80         90        100        110        120 
LLNKLIRSNL VDNTNQVEVL QRDPNSPLYS VKSFEELRLK PQLLQGVYAM GFNRPSKIQE 
       130        140        150        160        170        180 
NALPLMLAEP PQNLIAQSQS GTGKTAAFVL AMLSQVEPAN KYPQCLCLSP TYELALQTGK 
       190        200        210        220        230        240 
VIEQMGKFYP ELKLAYAVRG NKLERGQKIS EQIVIGTPGT VLDWCSKLKF IDPKKIKVFV 
       250        260        270        280        290        300 
LDEADVMIAT QGHQDQSIRI QRMLPRNCQM LLFSATFEDS VWKFAQKVVP DPNVIKLKRE 
       310        320        330        340        350        360 
EETLDTIKQY YVLCSSRDEK FQALCNLYGA ITIAQAMIFC HTRKTASWLA AELSKEGHQV 
       370        380        390        400        410        420 
ALLSGEMMVE QRAAVIERFR EGKEKVLVTT NVCARGIDVE QVSVVINFDL PVDKDGNPDN 
       430        440        450        460        470    
ETYLHRIGRT GRFGKRGLAV NMVDSKHSMN ILNRIQEHFN KKIERLDTDD LDEIEKIAN         10         20         30         40         50         60 
MATDSWALAV DEQEAAAESL SNLHLKEEKI KPDTNGAVVK TNANAEKTDE EEKEDRAAQS 
        70         80         90        100        110        120 
LLNKLIRSNL VDNTNQVEVL QRDPNSPLYS VKSFEELRLK PQLLQGVYAM GFNRPSKIQE 
       130        140        150        160        170        180 
NALPLMLAEP PQNLIAQSQS GTGKTAAFVL AMLSQVEPAN KYPQCLCLSP TYELALQTGK 
       190        200        210        220        230        240 
VIEQMGKFYP ELKLAYAVRG NKLERGQKIS EQIVIGTPGT VLDWCSKLKF IDPKKIKVFV 
       250        260        270        280        290        300 
LDEADVMIAT QGHQDQSIRI QRMLPRNCQM LLFSATFEDS VWKFAQKVVP DPNVIKLKRE 
       310        320        330        340        350        360 
EETLDTIKQY YVLCSSRDEK FQALCNLYGA ITIAQAMIFC HTRKTASWLA AELSKEGHQV 
       370        380        390        400        410        420 
ALLSGEMMVE QRAAVIERFR EGKEKVLVTT NVCARGIDVE QVSVVINFDL PVDKDGNPDN 
       430        440        450        460        470    
ETYLHRIGRT GRFGKRGLAV NMVDSKHSMN ILNRIQEHFN KKIERLDTDD LDEIEKIAN         10         20         30         40         50         60 
MATDSWALAV DEQEAAAESL SNLHLKEEKI KPDTNGAVVK TNANAEKTDE EEKEDRAAQS 
        70         80         90        100        110        120 
LLNKLIRSNL VDNTNQVEVL QRDPNSPLYS VKSFEELRLK PQLLQGVYAM GFNRPSKIQE 
       130        140        150        160        170        180 
NALPLMLAEP PQNLIAQSQS GTGKTAAFVL AMLSQVEPAN KYPQCLCLSP TYELALQTGK 
       190        200        210        220        230        240 
VIEQMGKFYP ELKLAYAVRG NKLERGQKIS EQIVIGTPGT VLDWCSKLKF IDPKKIKVFV 
       250        260        270        280        290        300 
LDEADVMIAT QGHQDQSIRI QRMLPRNCQM LLFSATFEDS VWKFAQKVVP DPNVIKLKRE 
       310        320        330        340        350        360 
EETLDTIKQY YVLCSSRDEK FQALCNLYGA ITIAQAMIFC HTRKTASWLA AELSKEGHQV 
       370        380        390        400        410        420 
ALLSGEMMVE QRAAVIERFR EGKEKVLVTT NVCARGIDVE QVSVVINFDL PVDKDGNPDN 
       430        440        450        460        470    
ETYLHRIGRT GRFGKRGLAV NMVDSKHSMN ILNRIQEHFN KKIERLDTDD LDEIEKIAN



Filter Information:


(REFRESH)

Directness:


Physiological Relevance:


Evidence Codes:


Methodology:


Perturbation of System:


Biological System:


Protease Assignment Confidence:


Evidence Names:


Database:


Lab:



Protein Neighborhood

Domains & Features

9 N-termini - 1 C-termini - 0 Cleavages - 0 Substrates

N-termini

C-termini

Cleavages

    Protease Position Sequence Evidence type Method Source (database) Source (Lab) Evidence name Publications (PMIDs)

Substrates

    Substrate Position Sequence Evidence type Method Source (database) Source (Lab) Evidence name Publications (PMIDs)