Ortholog conservation:

The wild-type residue R334 is highly conserved among the CFTR orthologs: 98% (49 / 50 CFTR orthologs)
The variant R334W has never been found among the CFTR orthologs

*AAPI: Alignment Average Percentage Identity
**AAPIR: Alignment Average Percentage Identity of the Region (20 residues surrounding position 334). AAPIR appears in green if it is more than 10% compared to AAPI, in red if less than 10%.
Click here for more details on the alignment.

CYSMA's visualizing modules for Ortholog conservation:

⬇ Download the region alignment (50 residues, Fasta format)
⬇ Download the CFTR phylogenic tree

Display methods

Domain conservation:

The residue p.Arg334 belongs to the domain MSD1.

69

422

MSD1: is the membrane-spanning domain 1, composed of six transmembrane helices (TM1-TM6).
Four of the six TMs protrude into the cytosol to form the intracellular loops ICL1 (between TM2 and TM3) and ICL2 (between TM4 and TM5). ICL1 contacts NBD1 at the level of the ATP-binding site, while ICL2 binds in a groove located at the surface of NBD2.

	is the membrane-spanning domain 1, composed of six transmembrane helices (TM1-TM6). Four of the six TMs protrude into the cytosol to form the intracellular loops ICL1 (between TM2 and TM3) and ICL2 (between TM4 and TM5). ICL1 contacts NBD1 at the level of the ATP-binding site, while ICL2 binds in a groove located at the surface of NBD2.

MSD1 of CF Transmembrane conductance Regulator domain alignment including p.Arg334 residue.

***AAPID: Alignment Average Percentage Identity of the Domain (positions are indicated).
^!AAPIR: Alignment Average Percentage Identity of the Region (20 residues surrounding position 334). AAPIR appears in green if it is more than 10% compared to AAPID, in red if less than 10%.

The wild-type residue R334 belongs to the MSD1 domain and is conserved at 10.96% among the MSD1 homologs (47 / 429 MSD1 homologs)
The variant R334W has never been found among the MSD1 homologs

Divergencies show the amino acids which have been selected in the evolution. Residues present in more than 10% of the sequences are highlighted in blue.
Please note that CYSMA does not consider splicing alterations.
Refer to the Help page for more details.

CYSMA's visualizing modules for MSD1 domain conservation:

Display methods

Secondary structure analysis:

Residue p.Arg334 is predicted to belong to an α helice. Probability is 0.525.

Direct environment is as follow:

G	I	I	L	R334	K	I	F	T

Observed frequencies in α helices:
R: 1.11
W: 0.98

Mutant residue is less observed in this type of structure.

Display methods

3D analysis:

Models provided and analysed by CYSMA must be considered as predictions, therefore be careful when interpreting the results. All efforts have been made to build structures of quality, however, they are provided with NO WARRANTY as to their accuracy with the real biological molecules studied.

Wild type and predicted mutant structures have been compared. You will find the results below.

• Overall quality of the structure:
  
  

  PDB template	Sequence identity*	MolProbity bad rotamers	MolProbity Ramachandran outliers	MolProbity Ramachandran favored
  5UAK	99.8 %	18/1313 - 1.37 %	17/1478 - 1.15 %	1360/1478 - 92.2 %

  
  
  

• Click on the MolProbity logo for complete details on the structure quality
  
  
  
  

• This model is made of 37 α helices and of 20 β strands (and is mainly composed of helices (739 residues in helices against 102 in strands, for a total of 1480 amino acids)).
  
  
• 3D structures predicts R334 to be located in an α helice (which confirms PsiPred prediction) and W334 in an α helice.
  Moreover, the residue is located in the first turn (N2) of this α helice (which contains 43 residues).
  N2 propensities of wild-type and mutant residues are 0.86 and 0.75.
  
  



CYSMA's modules to download the 3D structures:



Chech 3D coverage of CFTR models ⬇ Download the wild-type 3D structure (PDB format) ⬇ Download the mutant 3D model (PDB format)





CYSMA's 3D Automatic Annotation:





WARNING!
The experimental 3D structure used for our predictions is the complete human CFTR structure which have been solved at a 3.7 Å resolution using cryo-electron microscopy (PDB: 5UAK; Liu et al. 2017).
The overall resolution is fairly low so the CYSMA's 3D Automatic Annotation pipeline might have missed some important structural effects.




• Solvent accessibility: the wild-type R334 and the mutant R334W are predicted to be exposed
  
  
• The two residues have different charge properties, which could interfere with ionic bonds or potential inter- or intra-molecular interactions
  
  
• Hydrogen bond network:
  

  R334	W334
  none	distance: 3.08 Å / angle: 1.92 rad between TRP 334 NE1 and ASP 110 OD2

  
  
  
• The mutant residue might introduce steric clashes
  

  R334	W334
  none	2.98 Å between TRP 334 CB and LYS 335 N

  
  
  

CYSMA's 3D visualizing module:



• If you want to investigate further the structures, you can use the JSmol applets of the wild-type (left) and mutant (right) structures.
  
  Click on the JSmol applets' link to hide it.
  You have a full access to Jmol commands with a simple right click on one applet.
  
  
  
  
  

  R334 (wild-type)	W334 (mutant)

  
                Slab       Spin on/off       Show measurements       Change background       Sharper/Faster                    

  
  JSmol Legends:
  The residue at the position 334 is located in the center, labelled in yellow and surrounded by its neighboring residues (distance < 5 Å).
  Van der Waals contacts with the residue 334 are represented by dotted lines.
  Amino acids involved in H-bonds with the residue 334 are labelled in blue.
  Amino acids involved in steric clashes with the residue 334 are labelled in red.

  
  Display JSmol complete legends

  The overall structure of the complete human CFTR is represented in ribbon diagrams (click on the Reset button to visualize the overall CFTR structure).
  The membrane-spanning domain MSD1 is represented in blue and MSD2 in light blue.The nucleotide-binding domain NBD1 is represented in orange, NBD2 in light salmon.The lasso domain is shown in red and the R domain in green.

  Display Molecular Modelling methods

  The 3D structures used in CYSMA are models based on the CFTR experimental 3D structure in the channel-closed conformation (PDB: 5UAK; resolution: 3.9 Å).
  In the wild-type model, the (missing) loops and the (missing) R domain were built de novo using the software Modeller. For the variant models, the point mutation (homology modelling) are made on the fly with Modeller (more). Each structure has been assessed with MolProbity⁽¹⁹⁾. Msms⁽²⁰⁾ is used to calculate solvent accessibility, and STRIDE⁽²¹⁾ (plus stride2pdb) for secondary structure assignment.
  Secondary structure analyses in 3D models uses side chain interaction energies reviewed in ⁽²³⁾, as well as amino-acids propensities for N-caps, N1-N3, helix middle, C3-C1 and C-caps extracted from ⁽²⁴⁾(PDB values).
  Structural properties are calculated using an in-house developped program based for the USMA's 3D Automatic Annotation pipeline.

  Refer to the Help page for more details.

• Functional studies for c.1000C>T (R334W):
  
  

  Reference	PMID	Splicing	mRNA level	Maturation	Localization	Channel fonction (Cl-)	Bicarbonate
  Sheppard et al, 1993	7680769			✓	✓	✓
  Van Goor et al, 2014	23891399		✓	✓		✓
  Sosnay et al, 2013	23974870			✓		✓




« ✓ » indicates the type of analysis performed and not the results




• SIFT prediction: variant R334W is predicted to be damaging (score: 0)


• PPH2 prediction: variant R334W is predicted to be damaging (score: 1)


• UNIPROT annotations
  

  The variation is not reported in Uniprot.

• Click on the LOVD picture to check if a variant is described at position 334    
  
  
  
  



• Graphical display of the region at NCBI (including SNPs)



• CYSMA Report:

  
  

  Report for p.Arg334Trp variant

  CFTR orthologs conservation	The wild-type residue R334 is highly conserved among the CFTR orthologs: 98% (49 / 50 CFTR orthologs) The variant R334W has never been found among the CFTR orthologs
  MSD1 homologs conservation	The wild-type residue R334 belongs to the MSD1 domain and is conserved at 10.96% among the MSD1 homologs (47 / 429 MSD1 homologs) The variant R334W has never been found among the MSD1 homologs
  Structural effects	The wild-type residue R334 seems to play a key role in the CFTR function. R334 is involved in the pore construction Solvent accessibility: the wild-type R334 and the mutant R334W are predicted to be exposed The two residues have different charge properties, which could interfere with ionic bonds or potential inter- or intra-molecular interactions The mutant residue might introduce steric clashes
  Allele frequency	The variant R334W in gnomAD (123,136 exomes): 5.57e-05 ; variant R334W in gnomAD (15,496 genomes): 6.37e-05 The variant R334Q in gnomAD (123,136 exomes): 1.11e-04 ; variant R334Q in gnomAD (15,496 genomes): 6.37e-05 ; variant R334L in gnomAD (15,496 genomes): 3.19e-05
  Clinical significance	The variant R334W has been been described as Pathogenic - practice guideline - (ClinVar for more details)
  CFTR-France	The variant R334W might correspond to: NM_000492.3:c.1000C>T, which is reported to be disease-causing ( CFTR-France for more details)
  Additional resources	SIFT prediction: variant R334W is predicted to be damaging (score: 0) PPH2 prediction: variant R334W is predicted to be damaging (score: 1)