Phospho-TUBA1/3/4 (Tyr272) Antibody - #AF3944
Product Info
*The optimal dilutions should be determined by the end user.
*Tips:
WB: For western blot detection of denatured protein samples. IHC: For immunohistochemical detection of paraffin sections (IHC-p) or frozen sections (IHC-f) of tissue samples. IF/ICC: For immunofluorescence detection of cell samples. ELISA(peptide): For ELISA detection of antigenic peptide.
Cite Format: Affinity Biosciences Cat# AF3944, RRID:AB_2847667.
Fold/Unfold
Alpha tubulin ubiquitous; Alpha-tubulin ubiquitous; K alpha 1; TBA1B_HUMAN; TUBA1B; Tubulin alpha 1B; Tubulin alpha 1B chain; Tubulin alpha ubiquitous; Tubulin alpha ubiquitous chain; Tubulin alpha-1B chain; Tubulin alpha-ubiquitous chain; Tubulin K alpha 1; Tubulin K-alpha-1; Alpha-tubulin 1; ALS22; B ALPHA 1; bA408E5.3; H2 ALPHA; Hum a tub1; Hum a tub2; LIS3; MGC171407; MGC55332; TBA4A_HUMAN; Testis-specific alpha-tubulin; TUBA1; TUBA1A; tuba1l; Tuba4a; Tubulin alpha 1 chain; Tubulin alpha; Tubulin alpha-1 chain; tubulin alpha-1B chain; Tubulin alpha-4A chain; Tubulin H2-alpha; Tubulin, alpha 1 (testis specific); tubulin, alpha 1, like; Tubulin, alpha 4a; Tubulin, alpha, testis-specific; Tubulin, alpha-1; Alpha-tubulin 2; Alpha-tubulin 3C/D; alpha-tubulin isotype H2-alpha; H2-ALPHA; TBA3C_HUMAN; TUBA2; TUBA3C; TUBA3D; Tubulin alpha 2; Tubulin alpha 2 chain; Tubulin alpha 3c; Tubulin alpha-2 chain; Tubulin alpha-3C/D chain; Alpha tubulin 3; Alpha-tubulin 3; B alpha 1; FLJ25113; LIS3; TBA1A_HUMAN; TUBA1A; TUB
Immunogens
A synthesized peptide derived from human TUBA1/3/4 around the phosphorylation site of Tyr272.
Q71U36(TBA1A_HUMAN) >>Visit HPA database.
P68363(TBA1B_HUMAN) >>Visit HPA database.
Q9BQE3(TBA1C_HUMAN) >>Visit HPA database.
- Q71U36 TBA1A_HUMAN:
- Protein BLAST With
- NCBI/
- ExPASy/
- Uniprot
MRECISIHVGQAGVQIGNACWELYCLEHGIQPDGQMPSDKTIGGGDDSFNTFFSETGAGKHVPRAVFVDLEPTVIDEVRTGTYRQLFHPEQLITGKEDAANNYARGHYTIGKEIIDLVLDRIRKLADQCTGLQGFLVFHSFGGGTGSGFTSLLMERLSVDYGKKSKLEFSIYPAPQVSTAVVEPYNSILTTHTTLEHSDCAFMVDNEAIYDICRRNLDIERPTYTNLNRLIGQIVSSITASLRFDGALNVDLTEFQTNLVPYPRIHFPLATYAPVISAEKAYHEQLSVAEITNACFEPANQMVKCDPRHGKYMACCLLYRGDVVPKDVNAAIATIKTKRTIQFVDWCPTGFKVGINYQPPTVVPGGDLAKVQRAVCMLSNTTAIAEAWARLDHKFDLMYAKRAFVHWYVGEGMEEGEFSEAREDMAALEKDYEEVGVDSVEGEGEEEGEEY
- P68363 TBA1B_HUMAN:
- Protein BLAST With
- NCBI/
- ExPASy/
- Uniprot
MRECISIHVGQAGVQIGNACWELYCLEHGIQPDGQMPSDKTIGGGDDSFNTFFSETGAGKHVPRAVFVDLEPTVIDEVRTGTYRQLFHPEQLITGKEDAANNYARGHYTIGKEIIDLVLDRIRKLADQCTGLQGFLVFHSFGGGTGSGFTSLLMERLSVDYGKKSKLEFSIYPAPQVSTAVVEPYNSILTTHTTLEHSDCAFMVDNEAIYDICRRNLDIERPTYTNLNRLISQIVSSITASLRFDGALNVDLTEFQTNLVPYPRIHFPLATYAPVISAEKAYHEQLSVAEITNACFEPANQMVKCDPRHGKYMACCLLYRGDVVPKDVNAAIATIKTKRSIQFVDWCPTGFKVGINYQPPTVVPGGDLAKVQRAVCMLSNTTAIAEAWARLDHKFDLMYAKRAFVHWYVGEGMEEGEFSEAREDMAALEKDYEEVGVDSVEGEGEEEGEEY
- Q9BQE3 TBA1C_HUMAN:
- Protein BLAST With
- NCBI/
- ExPASy/
- Uniprot
MRECISIHVGQAGVQIGNACWELYCLEHGIQPDGQMPSDKTIGGGDDSFNTFFSETGAGKHVPRAVFVDLEPTVIDEVRTGTYRQLFHPEQLITGKEDAANNYARGHYTIGKEIIDLVLDRIRKLADQCTGLQGFLVFHSFGGGTGSGFTSLLMERLSVDYGKKSKLEFSIYPAPQVSTAVVEPYNSILTTHTTLEHSDCAFMVDNEAIYDICRRNLDIERPTYTNLNRLISQIVSSITASLRFDGALNVDLTEFQTNLVPYPRIHFPLATYAPVISAEKAYHEQLTVAEITNACFEPANQMVKCDPRHGKYMACCLLYRGDVVPKDVNAAIATIKTKRTIQFVDWCPTGFKVGINYQPPTVVPGGDLAKVQRAVCMLSNTTAVAEAWARLDHKFDLMYAKRAFVHWYVGEGMEEGEFSEAREDMAALEKDYEEVGADSADGEDEGEEY
- Q6PEY2 TBA3E_HUMAN:
- Protein BLAST With
- NCBI/
- ExPASy/
- Uniprot
MRECISIHVGQAGVQIGNACWELYCLEHGIQPDGQMPSDKTIGGGDDSFNTFFSETGAGKHVPRAVFVDLEPTVVDEVRTGTYRQLFHPEQLITGKEDAASNYARGHYTIGKEIVDLVLDRIRKLADLCTGLQGFLIFHSFGGGTGSGFASLLMERLSVDYSKKSKLEFAIYPAPQVSTAVVEPYNSILTTHTTLEHSDCAFMVDNEAIYDICRRNLDIERPTYTNLNRLIGQIVSSITASLRFDGALNVDLTEFQTNLVPYPRIHFPLATYAPVISAEKAYHEQLSVAEITNACFEPANQMVKCDPRHGKYMACCMLYRGDVVPKDVNAAIATIKTKRTIQFVDWCPTGFKVGINYQPPTVVPGGDLAKVQRAVCMLSNTTAIAEAWARLVHKFDLMYAKWAFVHWYVGEGMEEGEFSEAREDLAALEKDCEEVGVDSVEAEAEEGEAY
- P68366 TBA4A_HUMAN:
- Protein BLAST With
- NCBI/
- ExPASy/
- Uniprot
MRECISVHVGQAGVQMGNACWELYCLEHGIQPDGQMPSDKTIGGGDDSFTTFFCETGAGKHVPRAVFVDLEPTVIDEIRNGPYRQLFHPEQLITGKEDAANNYARGHYTIGKEIIDPVLDRIRKLSDQCTGLQGFLVFHSFGGGTGSGFTSLLMERLSVDYGKKSKLEFSIYPAPQVSTAVVEPYNSILTTHTTLEHSDCAFMVDNEAIYDICRRNLDIERPTYTNLNRLISQIVSSITASLRFDGALNVDLTEFQTNLVPYPRIHFPLATYAPVISAEKAYHEQLSVAEITNACFEPANQMVKCDPRHGKYMACCLLYRGDVVPKDVNAAIAAIKTKRSIQFVDWCPTGFKVGINYQPPTVVPGGDLAKVQRAVCMLSNTTAIAEAWARLDHKFDLMYAKRAFVHWYVGEGMEEGEFSEAREDMAALEKDYEEVGIDSYEDEDEGEE
PTMs - Q71U36/P68363/Q9BQE3/Q6PEY2/P68366 As Substrate
Site | PTM Type | Enzyme | Source |
---|---|---|---|
S6 | Phosphorylation | Uniprot | |
Y24 | Phosphorylation | Uniprot | |
S38 | Phosphorylation | Uniprot | |
K40 | Acetylation | Uniprot | |
K40 | Methylation | Uniprot | |
K40 | Ubiquitination | Uniprot | |
T41 | Phosphorylation | Uniprot | |
S48 | Phosphorylation | Uniprot | |
T51 | Phosphorylation | Uniprot | |
S54 | Phosphorylation | Uniprot | |
T56 | Phosphorylation | Uniprot | |
K60 | Acetylation | Uniprot | |
K60 | Sumoylation | Uniprot | |
K60 | Ubiquitination | Uniprot | |
T73 | Phosphorylation | Uniprot | |
T80 | Phosphorylation | Uniprot | |
T82 | Phosphorylation | Uniprot | |
Y83 | Phosphorylation | Uniprot | |
T94 | Phosphorylation | Uniprot | |
K96 | Acetylation | Uniprot | |
K96 | Sumoylation | Uniprot | |
K96 | Ubiquitination | Uniprot | |
Y103 | Phosphorylation | Uniprot | |
Y108 | Phosphorylation | Uniprot | |
T109 | Phosphorylation | Uniprot | |
K112 | Acetylation | Uniprot | |
K112 | Sumoylation | Uniprot | |
K112 | Ubiquitination | Uniprot | |
K124 | Acetylation | Uniprot | |
K124 | Ubiquitination | Uniprot | |
S151 | Phosphorylation | Uniprot | |
S158 | Phosphorylation | Uniprot | |
Y161 | Phosphorylation | Uniprot | |
K163 | Acetylation | Uniprot | |
K163 | Methylation | Uniprot | |
K163 | Ubiquitination | Uniprot | |
K164 | Ubiquitination | Uniprot | |
S165 | Phosphorylation | Uniprot | |
K166 | Ubiquitination | Uniprot | |
Y172 | Phosphorylation | Uniprot | |
Y185 | Phosphorylation | Uniprot | |
S187 | Phosphorylation | Uniprot | |
T190 | Phosphorylation | Uniprot | |
T191 | Phosphorylation | Uniprot | |
T193 | Phosphorylation | Uniprot | |
T194 | Phosphorylation | Uniprot | |
S198 | Phosphorylation | Uniprot | |
Y210 | Phosphorylation | Uniprot | |
T223 | Phosphorylation | Uniprot | |
Y224 | Phosphorylation | Uniprot | |
T225 | Phosphorylation | Uniprot | |
S236 | Phosphorylation | Uniprot | |
S237 | Phosphorylation | Uniprot | |
T253 | Phosphorylation | Uniprot | |
T257 | Phosphorylation | Uniprot | |
Y262 | Phosphorylation | Uniprot | |
T271 | Phosphorylation | Uniprot | |
Y272 | Phosphorylation | Uniprot | |
S277 | Phosphorylation | Uniprot | |
K280 | Ubiquitination | Uniprot | |
Y282 | Phosphorylation | Uniprot | |
S287 | Phosphorylation | Uniprot | |
T292 | Phosphorylation | Uniprot | |
K304 | Ubiquitination | Uniprot | |
K311 | Acetylation | Uniprot | |
K311 | Ubiquitination | Uniprot | |
Y312 | Phosphorylation | Uniprot | |
Y319 | Phosphorylation | Uniprot | |
K326 | Acetylation | Uniprot | |
K326 | Sumoylation | Uniprot | |
K326 | Ubiquitination | Uniprot | |
T334 | Phosphorylation | Uniprot | |
K336 | Acetylation | Uniprot | |
K336 | Sumoylation | Uniprot | |
K336 | Ubiquitination | Uniprot | |
T337 | Phosphorylation | Uniprot | |
K338 | Methylation | Uniprot | |
K338 | Ubiquitination | Uniprot | |
T340 | Phosphorylation | Uniprot | |
T349 | Phosphorylation | Uniprot | |
K352 | Acetylation | Uniprot | |
K352 | Sumoylation | Uniprot | |
K352 | Ubiquitination | Uniprot | |
Y357 | Phosphorylation | Uniprot | |
T361 | Phosphorylation | Uniprot | |
K370 | Acetylation | Uniprot | |
K370 | Sumoylation | Uniprot | |
K370 | Ubiquitination | Uniprot | |
S379 | Phosphorylation | Uniprot | |
K394 | Acetylation | Uniprot | |
K394 | Sumoylation | Uniprot | |
K394 | Ubiquitination | Uniprot | |
Y399 | Phosphorylation | Uniprot | |
K401 | Acetylation | Uniprot | |
K401 | Sumoylation | Uniprot | |
K401 | Ubiquitination | Uniprot | |
Y408 | Phosphorylation | Uniprot | |
S419 | Phosphorylation | Uniprot | |
K430 | Ubiquitination | Uniprot | |
Y432 | Phosphorylation | Uniprot | |
S439 | Phosphorylation | Uniprot | |
Y451 | Phosphorylation | Uniprot |
Site | PTM Type | Enzyme | Source |
---|---|---|---|
S6 | Phosphorylation | Uniprot | |
Y24 | Phosphorylation | Uniprot | |
S38 | Phosphorylation | Uniprot | |
K40 | Acetylation | Uniprot | |
K40 | Methylation | Uniprot | |
K40 | Ubiquitination | Uniprot | |
T41 | Phosphorylation | Uniprot | |
S48 | Phosphorylation | Uniprot | |
T51 | Phosphorylation | Uniprot | |
S54 | Phosphorylation | Uniprot | |
T56 | Phosphorylation | Uniprot | |
K60 | Acetylation | Uniprot | |
K60 | Sumoylation | Uniprot | |
K60 | Ubiquitination | Uniprot | |
T73 | Phosphorylation | Uniprot | |
T80 | Phosphorylation | Uniprot | |
T82 | Phosphorylation | Uniprot | |
Y83 | Phosphorylation | Uniprot | |
T94 | Phosphorylation | Uniprot | |
K96 | Acetylation | Uniprot | |
K96 | Sumoylation | Uniprot | |
K96 | Ubiquitination | Uniprot | |
Y103 | Phosphorylation | Uniprot | |
Y108 | Phosphorylation | Uniprot | |
T109 | Phosphorylation | Uniprot | |
K112 | Acetylation | Uniprot | |
K112 | Sumoylation | Uniprot | |
K112 | Ubiquitination | Uniprot | |
K124 | Acetylation | Uniprot | |
K124 | Ubiquitination | Uniprot | |
S151 | Phosphorylation | Uniprot | |
S158 | Phosphorylation | Uniprot | |
Y161 | Phosphorylation | Uniprot | |
K163 | Acetylation | Uniprot | |
K163 | Methylation | Uniprot | |
K163 | Ubiquitination | Uniprot | |
K164 | Ubiquitination | Uniprot | |
K166 | Ubiquitination | Uniprot | |
Y172 | Phosphorylation | Uniprot | |
Y185 | Phosphorylation | Uniprot | |
S187 | Phosphorylation | Uniprot | |
T190 | Phosphorylation | Uniprot | |
T191 | Phosphorylation | Uniprot | |
T193 | Phosphorylation | Uniprot | |
T194 | Phosphorylation | Uniprot | |
S198 | Phosphorylation | Uniprot | |
Y210 | Phosphorylation | Uniprot | |
T223 | Phosphorylation | Uniprot | |
Y224 | Phosphorylation | Uniprot | |
T225 | Phosphorylation | Uniprot | |
S232 | Phosphorylation | Uniprot | |
S236 | Phosphorylation | Uniprot | |
S237 | Phosphorylation | Uniprot | |
T239 | Phosphorylation | Uniprot | |
S241 | Phosphorylation | Uniprot | |
T253 | Phosphorylation | Uniprot | |
T257 | Phosphorylation | Uniprot | |
Y262 | Phosphorylation | Uniprot | |
T271 | Phosphorylation | Uniprot | |
Y272 | Phosphorylation | Uniprot | |
S277 | Phosphorylation | Uniprot | |
K280 | Acetylation | Uniprot | |
K280 | Ubiquitination | Uniprot | |
Y282 | Phosphorylation | Uniprot | |
S287 | Phosphorylation | Uniprot | |
T292 | Phosphorylation | Uniprot | |
C295 | S-Nitrosylation | Uniprot | |
K304 | Ubiquitination | Uniprot | |
K311 | Acetylation | Uniprot | |
K311 | Ubiquitination | Uniprot | |
Y312 | Phosphorylation | Uniprot | |
C315 | S-Nitrosylation | Uniprot | |
C316 | S-Nitrosylation | Uniprot | |
Y319 | Phosphorylation | Uniprot | |
K326 | Acetylation | Uniprot | |
K326 | Sumoylation | Uniprot | |
K326 | Ubiquitination | Uniprot | |
T334 | Phosphorylation | Uniprot | |
K336 | Acetylation | Uniprot | |
K336 | Sumoylation | Uniprot | |
K336 | Ubiquitination | Uniprot | |
T337 | Phosphorylation | Uniprot | |
K338 | Methylation | Uniprot | |
K338 | Ubiquitination | Uniprot | |
R339 | Methylation | Uniprot | |
S340 | Phosphorylation | Uniprot | |
C347 | S-Nitrosylation | Uniprot | |
T349 | Phosphorylation | Uniprot | |
K352 | Acetylation | Uniprot | |
K352 | Sumoylation | Uniprot | |
K352 | Ubiquitination | Uniprot | |
Y357 | Phosphorylation | Uniprot | |
T361 | Phosphorylation | Uniprot | |
K370 | Acetylation | Uniprot | |
K370 | Sumoylation | Uniprot | |
K370 | Ubiquitination | Uniprot | |
C376 | S-Nitrosylation | Uniprot | |
S379 | Phosphorylation | Uniprot | |
K394 | Acetylation | Uniprot | |
K394 | Methylation | Uniprot | |
K394 | Sumoylation | Uniprot | |
K394 | Ubiquitination | Uniprot | |
Y399 | Phosphorylation | Uniprot | |
K401 | Acetylation | Uniprot | |
K401 | Sumoylation | Uniprot | |
K401 | Ubiquitination | Uniprot | |
Y408 | Phosphorylation | Uniprot | |
S419 | Phosphorylation | Uniprot | |
K430 | Ubiquitination | Uniprot | |
Y432 | Phosphorylation | Uniprot | |
S439 | Phosphorylation | Uniprot | |
Y451 | Phosphorylation | Uniprot |
Site | PTM Type | Enzyme | Source |
---|---|---|---|
S6 | Phosphorylation | Uniprot | |
Y24 | Phosphorylation | Uniprot | |
S38 | Phosphorylation | Uniprot | |
K40 | Acetylation | Uniprot | |
K40 | Ubiquitination | Uniprot | |
T41 | Phosphorylation | Uniprot | |
S48 | Phosphorylation | Uniprot | |
T51 | Phosphorylation | Uniprot | |
S54 | Phosphorylation | Uniprot | |
T56 | Phosphorylation | Uniprot | |
K60 | Acetylation | Uniprot | |
K60 | Sumoylation | Uniprot | |
K60 | Ubiquitination | Uniprot | |
R79 | Methylation | Uniprot | |
T80 | Phosphorylation | Uniprot | |
T82 | Phosphorylation | Uniprot | |
T94 | Phosphorylation | Uniprot | |
R105 | Methylation | Uniprot | |
Y108 | Phosphorylation | Uniprot | |
T109 | Phosphorylation | Uniprot | |
R156 | Methylation | Uniprot | |
Y185 | Phosphorylation | Uniprot | |
S187 | Phosphorylation | Uniprot | |
T190 | Phosphorylation | Uniprot | |
T193 | Phosphorylation | Uniprot | |
T194 | Phosphorylation | Uniprot | |
S198 | Phosphorylation | Uniprot | |
Y210 | Phosphorylation | Uniprot | |
T223 | Phosphorylation | Uniprot | |
Y224 | Phosphorylation | Uniprot | |
T225 | Phosphorylation | Uniprot | |
S236 | Phosphorylation | Uniprot | |
S237 | Phosphorylation | Uniprot | |
T253 | Phosphorylation | Uniprot | |
T257 | Phosphorylation | Uniprot | |
Y262 | Phosphorylation | Uniprot | |
T271 | Phosphorylation | Uniprot | |
Y272 | Phosphorylation | Uniprot | |
S277 | Phosphorylation | Uniprot | |
K280 | Ubiquitination | Uniprot | |
Y282 | Phosphorylation | Uniprot | |
S287 | Phosphorylation | Uniprot | |
T292 | Phosphorylation | Uniprot | |
K304 | Ubiquitination | Uniprot | |
K326 | Acetylation | Uniprot | |
K326 | Sumoylation | Uniprot | |
K326 | Ubiquitination | Uniprot | |
T334 | Phosphorylation | Uniprot | |
K336 | Acetylation | Uniprot | |
K336 | Sumoylation | Uniprot | |
K336 | Ubiquitination | Uniprot | |
T337 | Phosphorylation | Uniprot | |
K338 | Methylation | Uniprot | |
K338 | Ubiquitination | Uniprot | |
T340 | Phosphorylation | Uniprot | |
T349 | Phosphorylation | Uniprot | |
K352 | Acetylation | Uniprot | |
K352 | Sumoylation | Uniprot | |
K352 | Ubiquitination | Uniprot | |
Y357 | Phosphorylation | Uniprot | |
T361 | Phosphorylation | Uniprot | |
K370 | Acetylation | Uniprot | |
K370 | Sumoylation | Uniprot | |
K370 | Ubiquitination | Uniprot | |
S379 | Phosphorylation | Uniprot | |
Y399 | Phosphorylation | Uniprot | |
K401 | Ubiquitination | Uniprot | |
Y408 | Phosphorylation | Uniprot | |
S419 | Phosphorylation | Uniprot |
Site | PTM Type | Enzyme | Source |
---|---|---|---|
S6 | Phosphorylation | Uniprot | |
Y24 | Phosphorylation | Uniprot | |
S38 | Phosphorylation | Uniprot | |
K40 | Acetylation | Uniprot | |
T41 | Phosphorylation | Uniprot | |
S48 | Phosphorylation | Uniprot | |
C54 | S-Nitrosylation | Uniprot | |
K60 | Ubiquitination | Uniprot | |
T73 | Phosphorylation | Uniprot | |
T94 | Phosphorylation | Uniprot | |
K96 | Acetylation | Uniprot | |
K96 | Sumoylation | Uniprot | |
K96 | Ubiquitination | Uniprot | |
Y103 | Phosphorylation | Uniprot | |
Y108 | Phosphorylation | Uniprot | |
T109 | Phosphorylation | Uniprot | |
K112 | Acetylation | Uniprot | |
K112 | Sumoylation | Uniprot | |
K112 | Ubiquitination | Uniprot | |
K124 | Methylation | Uniprot | |
K124 | Ubiquitination | Uniprot | |
S158 | Phosphorylation | Uniprot | |
Y161 | Phosphorylation | Uniprot | |
K163 | Acetylation | Uniprot | |
K163 | Methylation | Uniprot | |
K163 | Ubiquitination | Uniprot | |
K164 | Ubiquitination | Uniprot | |
K166 | Ubiquitination | Uniprot | |
Y172 | Phosphorylation | Uniprot | |
Y185 | Phosphorylation | Uniprot | |
S187 | Phosphorylation | Uniprot | |
T190 | Phosphorylation | Uniprot | |
T191 | Phosphorylation | Uniprot | |
T193 | Phosphorylation | Uniprot | |
T194 | Phosphorylation | Uniprot | |
S198 | Phosphorylation | Uniprot | |
Y210 | Phosphorylation | Uniprot | |
T223 | Phosphorylation | Uniprot | |
Y224 | Phosphorylation | Uniprot | |
T225 | Phosphorylation | Uniprot | |
S232 | Phosphorylation | Uniprot | |
S236 | Phosphorylation | Uniprot | |
S237 | Phosphorylation | Uniprot | |
T239 | Phosphorylation | Uniprot | |
S241 | Phosphorylation | Uniprot | |
T253 | Phosphorylation | Uniprot | |
T257 | Phosphorylation | Uniprot | |
Y262 | Phosphorylation | Uniprot | |
T271 | Phosphorylation | Uniprot | |
Y272 | Phosphorylation | Uniprot | |
S277 | Phosphorylation | Uniprot | |
K280 | Acetylation | Uniprot | |
K280 | Ubiquitination | Uniprot | |
Y282 | Phosphorylation | Uniprot | |
S287 | Phosphorylation | Uniprot | |
T292 | Phosphorylation | Uniprot | |
C295 | S-Nitrosylation | Uniprot | |
K304 | Ubiquitination | Uniprot | |
K311 | Acetylation | Uniprot | |
K311 | Ubiquitination | Uniprot | |
Y312 | Phosphorylation | Uniprot | |
Y319 | Phosphorylation | Uniprot | |
K326 | Ubiquitination | Uniprot | |
K336 | Sumoylation | Uniprot | |
K336 | Ubiquitination | Uniprot | |
K338 | Ubiquitination | Uniprot | |
R339 | Methylation | Uniprot | |
S340 | Phosphorylation | Uniprot | |
C347 | S-Nitrosylation | Uniprot | |
T349 | Phosphorylation | Uniprot | |
K352 | Acetylation | Uniprot | |
K352 | Sumoylation | Uniprot | |
K352 | Ubiquitination | Uniprot | |
Y357 | Phosphorylation | Uniprot | |
T361 | Phosphorylation | Uniprot | |
K370 | Acetylation | Uniprot | |
K370 | Sumoylation | Uniprot | |
K370 | Ubiquitination | Uniprot | |
C376 | S-Nitrosylation | Uniprot | |
S379 | Phosphorylation | Uniprot | |
K394 | Acetylation | Uniprot | |
K394 | Sumoylation | Uniprot | |
K394 | Ubiquitination | Uniprot | |
Y399 | Phosphorylation | Uniprot | |
K401 | Acetylation | Uniprot | |
K401 | Sumoylation | Uniprot | |
K401 | Ubiquitination | Uniprot | |
Y408 | Phosphorylation | Uniprot | |
S419 | Phosphorylation | Uniprot | |
Y432 | Phosphorylation | P43405 (SYK) | Uniprot |
S439 | Phosphorylation | Uniprot | |
Y440 | Phosphorylation | Uniprot |
Research Backgrounds
Tubulin is the major constituent of microtubules. It binds two moles of GTP, one at an exchangeable site on the beta chain and one at a non-exchangeable site on the alpha chain.
Some glutamate residues at the C-terminus are polyglutamylated, resulting in polyglutamate chains on the gamma-carboxyl group. Polyglutamylation plays a key role in microtubule severing by spastin (SPAST). SPAST preferentially recognizes and acts on microtubules decorated with short polyglutamate tails: severing activity by SPAST increases as the number of glutamates per tubulin rises from one to eight, but decreases beyond this glutamylation threshold.
Some glutamate residues at the C-terminus are monoglycylated but not polyglycylated due to the absence of functional TTLL10 in human. Monoglycylation is mainly limited to tubulin incorporated into axonemes (cilia and flagella). Both polyglutamylation and monoglycylation can coexist on the same protein on adjacent residues, and lowering glycylation levels increases polyglutamylation, and reciprocally. The precise function of monoglycylation is still unclear (Probable).
Acetylation of alpha chains at Lys-40 is located inside the microtubule lumen. This modification has been correlated with increased microtubule stability, intracellular transport and ciliary assembly.
Methylation of alpha chains at Lys-40 is found in mitotic microtubules and is required for normal mitosis and cytokinesis contributing to genomic stability.
Nitration of Tyr-451 is irreversible and interferes with normal dynein intracellular distribution.
Undergoes a tyrosination/detyrosination cycle, the cyclic removal and re-addition of a C-terminal tyrosine residue by the enzymes tubulin tyrosine carboxypeptidase (VASH1 or VASH2) and tubulin tyrosine ligase (TTL), respectively.
Tyrosination promotes microtubule interaction with CAP-Gly domain-containing proteins such as CLIP1, CLIP2 and DCTN1. Tyrosination regulates the initiation of dynein-dynactin motility via interaction with DCTN1, which brings the dynein-dynactin complex into contact with microtubules. In neurons, tyrosinated tubulins mediate the initiation of retrograde vesicle transport.
Detyrosination is involved in metaphase plate congression by guiding chromosomes during mitosis: detyrosination promotes interaction with CENPE, promoting pole-proximal transport of chromosomes toward the equator. Detyrosination increases microtubules-dependent mechanotransduction in dystrophic cardiac and skeletal muscle. In cardiomyocytes, detyrosinated microtubules are required to resist to contractile compression during contraction: detyrosination promotes association with desmin (DES) at force-generating sarcomeres, leading to buckled microtubules and mechanical resistance to contraction (By similarity).
Cytoplasm>Cytoskeleton.
Expressed at a high level in fetal brain.
Dimer of alpha and beta chains. A typical microtubule is a hollow water-filled tube with an outer diameter of 25 nm and an inner diameter of 15 nM. Alpha-beta heterodimers associate head-to-tail to form protofilaments running lengthwise along the microtubule wall with the beta-tubulin subunit facing the microtubule plus end conferring a structural polarity. Microtubules usually have 13 protofilaments but different protofilament numbers can be found in some organisms and specialized cells. Interacts with SETD2; the interaction is independent on alpha-tubulin acetylation on Lys-40.
Belongs to the tubulin family.
Tubulin is the major constituent of microtubules. It binds two moles of GTP, one at an exchangeable site on the beta chain and one at a non-exchangeable site on the alpha chain.
Some glutamate residues at the C-terminus are polyglutamylated, resulting in polyglutamate chains on the gamma-carboxyl group. Polyglutamylation plays a key role in microtubule severing by spastin (SPAST). SPAST preferentially recognizes and acts on microtubules decorated with short polyglutamate tails: severing activity by SPAST increases as the number of glutamates per tubulin rises from one to eight, but decreases beyond this glutamylation threshold.
Some glutamate residues at the C-terminus are monoglycylated but not polyglycylated due to the absence of functional TTLL10 in human. Monoglycylation is mainly limited to tubulin incorporated into axonemes (cilia and flagella). Both polyglutamylation and monoglycylation can coexist on the same protein on adjacent residues, and lowering glycylation levels increases polyglutamylation, and reciprocally. The precise function of monoglycylation is still unclear (Probable).
Acetylation of alpha chains at Lys-40 is located inside the microtubule lumen. This modification has been correlated with increased microtubule stability, intracellular transport and ciliary assembly.
Methylation of alpha chains at Lys-40 is found in mitotic microtubules and is required for normal mitosis and cytokinesis contributing to genomic stability.
Nitration of Tyr-451 is irreversible and interferes with normal dynein intracellular distribution.
Undergoes a tyrosination/detyrosination cycle, the cyclic removal and re-addition of a C-terminal tyrosine residue by the enzymes tubulin tyrosine carboxypeptidase (VASH1 or VASH2) and tubulin tyrosine ligase (TTL), respectively.
Tyrosination promotes microtubule interaction with CAP-Gly domain-containing proteins such as CLIP1, CLIP2 and DCTN1 (By similarity). Tyrosination regulates the initiation of dynein-dynactin motility via interaction with DCTN1, which brings the dynein-dynactin complex into contact with microtubules. In neurons, tyrosinated tubulins mediate the initiation of retrograde vesicle transport (By similarity).
Detyrosination is involved in metaphase plate congression by guiding chromosomes during mitosis: detyrosination promotes interaction with CENPE, promoting pole-proximal transport of chromosomes toward the equator. Detyrosination increases microtubules-dependent mechanotransduction in dystrophic cardiac and skeletal muscle. In cardiomyocytes, detyrosinated microtubules are required to resist to contractile compression during contraction: detyrosination promotes association with desmin (DES) at force-generating sarcomeres, leading to buckled microtubules and mechanical resistance to contraction (By similarity).
Cytoplasm>Cytoskeleton.
Dimer of alpha and beta chains. A typical microtubule is a hollow water-filled tube with an outer diameter of 25 nm and an inner diameter of 15 nM. Alpha-beta heterodimers associate head-to-tail to form protofilaments running lengthwise along the microtubule wall with the beta-tubulin subunit facing the microtubule plus end conferring a structural polarity. Microtubules usually have 13 protofilaments but different protofilament numbers can be found in some organisms and specialized cells.
Belongs to the tubulin family.
Tubulin is the major constituent of microtubules. It binds two moles of GTP, one at an exchangeable site on the beta chain and one at a non-exchangeable site on the alpha chain.
Some glutamate residues at the C-terminus are polyglutamylated, resulting in polyglutamate chains on the gamma-carboxyl group. Polyglutamylation plays a key role in microtubule severing by spastin (SPAST). SPAST preferentially recognizes and acts on microtubules decorated with short polyglutamate tails: severing activity by SPAST increases as the number of glutamates per tubulin rises from one to eight, but decreases beyond this glutamylation threshold.
Some glutamate residues at the C-terminus are monoglycylated but not polyglycylated due to the absence of functional TTLL10 in human. Monoglycylation is mainly limited to tubulin incorporated into axonemes (cilia and flagella). Both polyglutamylation and monoglycylation can coexist on the same protein on adjacent residues, and lowering glycylation levels increases polyglutamylation, and reciprocally. The precise function of monoglycylation is still unclear (Probable).
Acetylation of alpha chains at Lys-40 is located inside the microtubule lumen. This modification has been correlated with increased microtubule stability, intracellular transport and ciliary assembly.
Methylation of alpha chains at Lys-40 is found in mitotic microtubules and is required for normal mitosis and cytokinesis contributing to genomic stability.
Nitration of Tyr-449 is irreversible and interferes with normal dynein intracellular distribution.
Undergoes a tyrosination/detyrosination cycle, the cyclic removal and re-addition of a C-terminal tyrosine residue by the enzymes tubulin tyrosine carboxypeptidase (VASH1 or VASH2) and tubulin tyrosine ligase (TTL), respectively.
Tyrosination promotes microtubule interaction with CAP-Gly domain-containing proteins such as CLIP1, CLIP2 and DCTN1 (By similarity). Tyrosination regulates the initiation of dynein-dynactin motility via interaction with DCTN1, which brings the dynein-dynactin complex into contact with microtubules. In neurons, tyrosinated tubulins mediate the initiation of retrograde vesicle transport (By similarity).
Detyrosination is involved in metaphase plate congression by guiding chromosomes during mitosis: detyrosination promotes interaction with CENPE, promoting pole-proximal transport of chromosomes toward the equator. Detyrosination increases microtubules-dependent mechanotransduction in dystrophic cardiac and skeletal muscle. In cardiomyocytes, detyrosinated microtubules are required to resist to contractile compression during contraction: detyrosination promotes association with desmin (DES) at force-generating sarcomeres, leading to buckled microtubules and mechanical resistance to contraction (By similarity).
Cytoplasm>Cytoskeleton.
Dimer of alpha and beta chains. A typical microtubule is a hollow water-filled tube with an outer diameter of 25 nm and an inner diameter of 15 nM. Alpha-beta heterodimers associate head-to-tail to form protofilaments running lengthwise along the microtubule wall with the beta-tubulin subunit facing the microtubule plus end conferring a structural polarity. Microtubules usually have 13 protofilaments but different protofilament numbers can be found in some organisms and specialized cells.
Belongs to the tubulin family.
Tubulin is the major constituent of microtubules. It binds two moles of GTP, one at an exchangeable site on the beta chain and one at a non-exchangeable site on the alpha chain (By similarity).
Some glutamate residues at the C-terminus are polyglutamylated, resulting in polyglutamate chains on the gamma-carboxyl group. Polyglutamylation plays a key role in microtubule severing by spastin (SPAST). SPAST preferentially recognizes and acts on microtubules decorated with short polyglutamate tails: severing activity by SPAST increases as the number of glutamates per tubulin rises from one to eight, but decreases beyond this glutamylation threshold.
Some glutamate residues at the C-terminus are monoglycylated but not polyglycylated due to the absence of functional TTLL10 in human. Monoglycylation is mainly limited to tubulin incorporated into axonemes (cilia and flagella). Both polyglutamylation and monoglycylation can coexist on the same protein on adjacent residues, and lowering glycylation levels increases polyglutamylation, and reciprocally. The precise function of monoglycylation is still unclear (Probable).
Acetylation of alpha chains at Lys-40 is located inside the microtubule lumen. This modification has been correlated with increased microtubule stability, intracellular transport and ciliary assembly.
Methylation of alpha chains at Lys-40 is found in mitotic microtubules and is required for normal mitosis and cytokinesis contributing to genomic stability.
Nitration of Tyr-450 is irreversible and interferes with normal dynein intracellular distribution.
Undergoes a tyrosination/detyrosination cycle, the cyclic removal and re-addition of a C-terminal tyrosine residue by the enzymes tubulin tyrosine carboxypeptidase (VASH1 or VASH2) and tubulin tyrosine ligase (TTL), respectively.
Tyrosination promotes microtubule interaction with CAP-Gly domain-containing proteins such as CLIP1, CLIP2 and DCTN1 (By similarity). Tyrosination regulates the initiation of dynein-dynactin motility via interaction with DCTN1, which brings the dynein-dynactin complex into contact with microtubules. In neurons, tyrosinated tubulins mediate the initiation of retrograde vesicle transport (By similarity).
Detyrosination is involved in metaphase plate congression by guiding chromosomes during mitosis: detyrosination promotes interaction with CENPE, promoting pole-proximal transport of chromosomes toward the equator. Detyrosination increases microtubules-dependent mechanotransduction in dystrophic cardiac and skeletal muscle. In cardiomyocytes, detyrosinated microtubules are required to resist to contractile compression during contraction: detyrosination promotes association with desmin (DES) at force-generating sarcomeres, leading to buckled microtubules and mechanical resistance to contraction (By similarity).
Cytoplasm>Cytoskeleton.
Dimer of alpha and beta chains. A typical microtubule is a hollow water-filled tube with an outer diameter of 25 nm and an inner diameter of 15 nM. Alpha-beta heterodimers associate head-to-tail to form protofilaments running lengthwise along the microtubule wall with the beta-tubulin subunit facing the microtubule plus end conferring a structural polarity. Microtubules usually have 13 protofilaments but different protofilament numbers can be found in some organisms and specialized cells.
Belongs to the tubulin family.
Tubulin is the major constituent of microtubules. It binds two moles of GTP, one at an exchangeable site on the beta chain and one at a non-exchangeable site on the alpha chain.
Some glutamate residues at the C-terminus are polyglutamylated, resulting in polyglutamate chains on the gamma-carboxyl group. Polyglutamylation plays a key role in microtubule severing by spastin (SPAST). SPAST preferentially recognizes and acts on microtubules decorated with short polyglutamate tails: severing activity by SPAST increases as the number of glutamates per tubulin rises from one to eight, but decreases beyond this glutamylation threshold.
Some glutamate residues at the C-terminus are monoglycylated but not polyglycylated due to the absence of functional TTLL10 in human. Monoglycylation is mainly limited to tubulin incorporated into axonemes (cilia and flagella). Both polyglutamylation and monoglycylation can coexist on the same protein on adjacent residues, and lowering glycylation levels increases polyglutamylation, and reciprocally. The precise function of monoglycylation is still unclear (Probable).
Acetylation of alpha chains at Lys-40 is located inside the microtubule lumen. This modification has been correlated with increased microtubule stability, intracellular transport and ciliary assembly.
Methylation of alpha chains at Lys-40 is found in mitotic microtubules and is required for normal mitosis and cytokinesis contributing to genomic stability.
Cytoplasm>Cytoskeleton.
Dimer of alpha and beta chains. A typical microtubule is a hollow water-filled tube with an outer diameter of 25 nm and an inner diameter of 15 nM. Alpha-beta heterodimers associate head-to-tail to form protofilaments running lengthwise along the microtubule wall with the beta-tubulin subunit facing the microtubule plus end conferring a structural polarity. Microtubules usually have 13 protofilaments but different protofilament numbers can be found in some organisms and specialized cells. Interacts with CFAP157 (By similarity).
Belongs to the tubulin family.
Research Fields
· Cellular Processes > Transport and catabolism > Phagosome. (View pathway)
· Cellular Processes > Cell growth and death > Apoptosis. (View pathway)
· Cellular Processes > Cellular community - eukaryotes > Tight junction. (View pathway)
· Cellular Processes > Cellular community - eukaryotes > Gap junction. (View pathway)
· Human Diseases > Infectious diseases: Bacterial > Pathogenic Escherichia coli infection.
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