Space group determination

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Space groups as combinations of symmetry elements

Space group determination entails the following steps:

  1. determine the Laue class: this is the symmetry of the intensity-weighted point lattice (diffraction pattern). 1,2,3,4,6=n-fold rotation axis; -n means inversion centre (normally the - is written over the n); m means mirror.
  2. find out about Bravais type: the second letter signifies centering (P=primitive; C=centered on C-face; F=centered on all faces; I=body-centered; R=rhombohedral). The first letter (a=triclinic; m=monoclinic; o=orthorhombic; h=trigonal or hexagonal; c=cubic) is redundant since it can be inferred from the Laue group.
  3. possible spacegroups are now given in columns 3 and 4; CORRECT always suggests the one given in column 3 but this is no more likely than those in column 4.
  4. choose according to screw axis (according to the table "REFLECTIONS OF TYPE H,0,0 0,K,0 0,0,L OR EXPECTED TO BE ABSENT (*)" in CORRECT.LP); this may result in two possibilities (enantiomorphs).
  5. determine correct enantiomorph - this usually means that one tries to solve the structure in both spacegroups, and only one gives a sensible result (like helices that are right-handed, amino acids of the L type).


Table of space groups by Laue class and Bravais type

Laue class Bravais type spacegroup
number
suggested by
CORRECT
other possibilities (due to screw axes) alternative indexing
possible?
choosing among all spacegroup possibilities
-1 aP 1 -
2/m mP 3 4 screw axis extinctions let you decide
2/m mC 5 - The pointless article discusses why I2 (mI) should not be used.
mmm oP 16 17, 18, 19 screw axis extinctions let you decide. The pointless article discusses why CCP4's 1017 (P2122), 2017 (P2212), 2018 (P21221) , 3018 (P22121) are not needed and should not be used.
mmm oC 21 20 screw axis extinctions let you decide
mmm oF 22 -
mmm oI 23 24 screw axis extinctions do not let you decide because the I centering results in h+k+l=2n and the screw axis extinction 00l=2n is just a special case of that. 23/24 do not form an enantiomorphic, but a special pair (ITC A §3.5, p. 46 in the 1995 edition).
4/m tP 75 76, 77, 78 k,h,-l screw axis extinctions let you decide, except between 76/78 enantiomorphs
4/m tI 79 80 k,h,-l screw axis extinctions let you decide
4/mmm tP 89 90, 91, 92, 93, 94, 95, 96 screw axis extinctions let you decide, except between 91/95 and 92/96 enantiomorphs
4/mmm tI 97 98 screw axis extinctions let you decide
-3 hP 143 144, 145 -h,-k,l; k,h,-l; -k,-h,-l screw axis extinctions let you decide, except between 144/145 enantiomorphs
-3 hR 146 - k,h,-l, and obverse (-h+k+l=3n) / reverse (h-k+l=3n)
-3/m hP 149 151, 153 k,h,-l screw axis extinctions let you decide, except between 151/153 enantiomorphs. Note: the twofold goes along the diagonal between a and b.
-3/m hP 150 152, 154 -h,-k,l screw axis extinctions let you decide, except between 152/154 enantiomorphs. Note: compared to previous line, the twofold goes along a.
-3/m hR 155 - obverse/reverse
6/m hP 168 169, 170, 171, 172, 173 k,h,-l screw axis extinctions let you decide, except between 169/170 and 171/172 enantiomorphs
6/mmm hP 177 178, 179, 180, 181, 182 screw axis extinctions let you decide, except between 178/179 and 180/181 enantiomorphs
m-3 cP 195 198 k,h,-l screw axis extinctions let you decide
m-3 cF 196 - k,h,-l
m-3 cI 197 199 k,h,-l screw axis extinctions do not let you decide because the I centering results in h+k+l=2n and the screw axis extinction 00l=2n is just a special case of that. 197/199 do not form an enantiomorphic, but a special pair (ITC A §3.5, p. 46 in the 1995 edition).
m-3m cP 207 208, 212, 213 screw axis extinctions let you decide, except between 212/213 enantiomorphs
m-3m cF 209 210 screw axis extinctions let you decide
m-3m cI 211 214 screw axis extinctions let you decide

Alternative indexing possibilities taken from http://www.ccp4.ac.uk/html/reindexing.html (for R3 and R32, obverse/reverse are specified). If you find an error in the table please send an email to kay dot diederichs at uni-konstanz dot de !

The 65 Sohncke space groups in which proteins composed of L-amino acids can crystallize

The mapping of numbers and names is:

****** LATTICE SYMMETRY IMPLICATED BY SPACE GROUP SYMMETRY ******

BRAVAIS-           POSSIBLE SPACE-GROUPS FOR PROTEIN CRYSTALS
 TYPE                     [SPACE GROUP NUMBER,SYMBOL]
 aP      [1,P1]
 mP      [3,P2] [4,P2(1)]
mC,mI    [5,C2]
 oP      [16,P222] [17,P222(1)] [18,P2(1)2(1)2] [19,P2(1)2(1)2(1)]
 oC      [21,C222] [20,C222(1)]
 oF      [22,F222]
 oI      [23,I222] [24,I2(1)2(1)2(1)]
 tP      [75,P4] [76,P4(1)] [77,P4(2)] [78,P4(3)] [89,P422] [90,P42(1)2]
         [91,P4(1)22] [92,P4(1)2(1)2] [93,P4(2)22] [94,P4(2)2(1)2]
         [95,P4(3)22] [96,P4(3)2(1)2]
 tI      [79,I4] [80,I4(1)] [97,I422] [98,I4(1)22]
 hP      [143,P3] [144,P3(1)] [145,P3(2)] [149,P312] [150,P321] [151,P3(1)12]
         [152,P3(1)21] [153,P3(2)12] [154,P3(2)21] [168,P6] [169,P6(1)]
         [170,P6(5)] [171,P6(2)] [172,P6(4)] [173,P6(3)] [177,P622]
         [178,P6(1)22] [179,P6(5)22] [180,P6(2)22] [181,P6(4)22] [182,P6(3)22]
 hR      [146,R3] [155,R32]
 cP      [195,P23] [198,P2(1)3] [207,P432] [208,P4(2)32] [212,P4(3)32]
         [213,P4(1)32]
 cF      [196,F23] [209,F432] [210,F4(1)32]
 cI      [197,I23] [199,I2(1)3] [211,I432] [214,I4(1)32]


Subgroup and supergroup relations of these space groups

Compiled from International Tables for Crystallography (2006) Vol. A1 (Wiley). Simply put, for each space group, a maximum translationengleiche subgroup has lost a single type of symmetry, and a minimum translationengleiche supergroup has gained a single symmetry type. Example: P222 is a supergroup of P2, and a subgroup of P422 (and P4222 and P23). Of course the sub-/supergroup relation is recursive, which is why P1 is also a (sub-)subgroup of P222 (but not a maximum translationengleiche subgroup). The table below does not show other types of relations, e.g. non-isomorphic klassengleiche supergroups which may result e.g. from centring translations, because I find them less relevant in space group determination.

The table is relevant because in particular twinning adds a symmetry type, and leads to an apparent space group which is the supergroup of the true space group.

spacegroup number maximum translationengleiche subgroup minimum translationengleiche supergroup spacegroup name
1 - 3, 4, 5, 143, 144, 145, 146 P 1
3 1 16, 17, 18, 21, 75, 77, 168, 171, 172 P 2
4 1 17, 18, 19, 20, 76, 78, 169, 170, 173 P 21
5 1 20, 21, 22, 23, 24, 79, 80, 149, 150, 151, 152, 153, 154, 155 C2
16 3 89, 93, 195 P 2 2 2
17 3, 4 91, 95 P 2 2 21
18 3, 4 90, 94 P 21 21 2
19 4 92, 96, 198 P 21 21 21
20 4, 5 91, 92, 95, 96, 178, 179, 182 C 2 2 21
21 3, 5 89, 90, 93, 94, 177, 180, 181 C 2 2 2
22 5 97, 98, 196 F 2 2 2
23 5 97, 197 I 2 2 2
24 5 98, 199 I 21 21 21
75 3 89, 90 P 4
76 4 91, 92 P 41
77 3 93, 94 P 42
78 4 95, 96 P 43
79 5 97 I 4
80 5 98 I 41
89 16, 21, 75 207 P 4 2 2
90 18, 21, 75 - P 4 21 2
91 17, 20, 76 - P 41 2 2
92 19, 20, 76 213 P 41 21 2
93 16, 21, 77 208 P 42 2 2
94 18, 21, 77 93, 97 P 42 21 2
95 17, 20, 78 - P 43 2 2
96 19, 20, 78 212 P 43 21 2
97 22, 23, 79 209, 211 I 4 2 2
98 22, 24, 80 210, 214 I 41 2 2
143 1 149, 150, 168, 173 P 3
144 1 151, 152, 169, 172 P 31
145 1 153, 154, 170, 171 P 32
146 1 155, 195, 196, 197, 198, 199 R 3
149 5, 143 177, 182 P 3 1 2
150 5, 143 177, 182 P 3 2 1
151 5, 144 178, 181 P 31 1 2
152 5, 144 178, 181 P 31 2 1
153 5, 145 179, 180 P 32 1 2
154 5, 145 179, 180 P 32 2 1
155 5, 146 207, 208, 209, 210, 211, 212, 213, 214 R 3 2
168 3, 143 177 P 6
169 4, 144 178 P 61
170 4, 145 179 P 65
171 3, 145 180 P 62
172 3, 144 181 P 64
173 4, 143 182 P 63
177 21, 149, 150, 168 - P 6 2 2
178 20, 151, 152, 169 - P 61 2 2
179 20, 153, 154, 170 - P 65 2 2
180 21, 153, 154, 171 - P 62 2 2
181 21, 151, 152, 172 - P 64 2 2
182 20, 149, 150, 173 - P 63 2 2
195 16, 146 207, 208 P 2 3
196 22, 146 209, 210 F 2 3
197 23, 146 211 I 2 3
198 19, 146 212, 213 P 21 3
199 24, 146 214 I 21 3
207 89, 155, 195 - P 4 3 2
208 93, 155, 195 - P 42 3 2
209 97, 155, 196 - F 4 3 2
210 98, 155, 196 - F 41 3 2
211 97, 155, 197 - I 4 3 2
212 96, 155, 198 - P 43 3 2
213 92, 155, 198 - P 41 3 2
214 98, 155, 199 - I 41 3 2

Space group selected by XDS: ambiguous with respect to enantiomorph and screw axes

In case of a crystal with an unknown space group (SPACE_GROUP_NUMBER=0 in XDS.INP), XDS (since version June 2008) helps the user in determination of the correct space group, by suggesting possible space groups compatible with the Laue symmetry and Bravais type of the data, and by calculating the Rmeas for these space groups.

XDS (or rather, the CORRECT step) makes an attempt to pick the correct space group automatically: it chooses that space group which has the highest symmetry (thus yielding the lowest number of unique reflections) and still a tolerable Rmeas compared to the Rmeas the data have in any space group (which is most likely a low-symmetry space group - often P1).

In some cases the automatic choice is the correct one, and re-running the CORRECT step is then not necessary. However, neither the correct enantiomorph nor screw axes (see below) are determined automatically by XDS.

Space group selected by user

In case the space group selected by XDS should be incorrect, the resulting list (in CORRECT.LP) should give the user enough information to pick the correct space group herself (alternatives are in the big table above!). The user may then put suitable lines with SPACE_GROUP_NUMBER=, UNIT_CELL_CONSTANTS= into XDS.INP and re-run the CORRECT step to obtain the desired result. (The REIDX= line is no longer required; XDS figures the matrix out.)

Influencing the selection by XDS

keywords and parameters

The automatic choice is influenced by a number of decision constants that may be put into XDS.INP but which have defaults as indicated below:

  • MAX_CELL_AXIS_ERROR= 0.03  ! relative deviation of unconstrained cell axes from those constrained by lattice symmetry
  • MAX_CELL_ANGLE_ERROR= 3.0  ! degrees deviation of unconstrained cell angles from those constrained by lattice symmetry
  • TEST_RESOLUTION_RANGE= 10.0 5.0 ! resolution range for calculation of Rmeas
  • MIN_RFL_Rmeas= 50  ! at least this number of reflections are required
  • MAX_FAC_Rmeas= 2.0  ! factor to multiply the lowest Rmeas with to still be acceptable

The user may experiment with adjusting these values to make the automatic mode of space group determination more successful. For example, if the crystal diffracts weakly, all Rmeas values will be high and no valid decision can be made. In this case, I suggest to use e.g.

TEST_RESOLUTION_RANGE= 50.0 10.0

dealing with alternative indexing

There are two ways to have XDS choose an indexing consistent with some other dataset:

  • using REFERENCE_DATA_SET=  ! see also REFERENCE_DATA_SET
  • using UNIT_CELL_A-AXIS=, UNIT_CELL_B-AXIS=, UNIT_CELL_C-AXIS= from a previous data collection run with the same crystal

One can also manually force a specific indexing, using the REIDX= keyword, but this is error-prone.

See also http://www.ccp4.ac.uk/html/reindexing.html

Screw axes

The current version makes no attempt to find out about screw axes. It is assumed that the user checks the table in CORRECT.LP entitled REFLECTIONS OF TYPE H,0,0 0,K,0 0,0,L OR EXPECTED TO BE ABSENT (*), and identifies whether the intensities follow the rules

  1. a two-fold screw axis along an axis in reciprocal space (theoretically) results in zero intensity for the odd-numbered (e.g. 0,K,0 with K = 2*n + 1) reflections, leaving the reflections of type 2*n as candidates for medium to strong reflections (they don't have to be strong, but they may be strong!).
  2. similarly, a three-fold screw axis (theoretically) results in zero intensity for the reflections of type 3*n+1 and 3*n+2, and allows possibly strong 3*n reflections . 31 and 32 cannot be distinguished - they are enantiomorphs.
  3. analogously for four-fold screw axes: for H=0, K=0 reflections, 41 and 43 screws yield the rule L=4*n, and 42 yields the rule L=2*n .
  4. analogously for six-fold screw axes: for H=0, K=0 reflections, 61 and 65 screws yield the rule L=6*n, 62 and 64 yield the rule L=3*n, and 63 yields the rule L=2*n .

Once screw axes have been deduced from the patterns of intensities along H,0,0 0,K,0 0,0,L , the resulting space group should be identified in the lists of space group numbers printed in IDXREF.LP and CORRECT.LP, and the CORRECT step can be re-run. Those reflections that should theoretically have zero intensity are then marked with a "*" in the table. In practice, they should be (hopefully quite) weak, or even negative.

Notes

  • There is still the old Wiki page Old way of Space group determination
  • To prevent XDS from trying to find a better space group than the one with the lowest Rmeas (often P1), you could just use MAX_FAC_Rmeas= 1.0
  • Space group determination is not a trivial task. There is a number of difficulties that arise -
    • ambiguity of hand of screw axis (e.g. 31 versus 32, or 62 versus 64) - see the table above!
    • twinning may make a low-symmetry space group look like a high-symmetry one
  • pointless helps with identification of screw axes, and its identification of Laue group is more sensitive than that implemented in CORRECT. However it is not fail-safe, and cannot tell the correct enantiomorph.
  • only when the structure is satisfactorily refined can the chosen space group be considered established and correct. Until then, it is just a hypothesis and its alternatives (see the table) should be kept in mind.

An example

The following example shows the difficulty in deciding between higher and lower symmetry.

IDXREF reports:

  LATTICE-  BRAVAIS-   QUALITY  UNIT CELL CONSTANTS (ANGSTROEM & DEGREES)
 CHARACTER  LATTICE     OF FIT      a      b      c   alpha  beta gamma

 *  44        aP          0.0      74.0   78.6  124.0 108.2 105.1  90.4
 *  31        aP          3.5      74.0   78.6  124.0  71.8  74.9  90.4
 *  41        mC          7.4     235.7   78.6   74.0  90.4 106.1  89.7
 *  37        mC         34.8     239.6   74.0   78.6  90.4 109.0  87.8
 *  42        oI         38.7      74.0   78.6  226.6  90.2  92.2  90.4
    14        mC        122.5     107.6  108.3  124.0  92.8 114.1  86.6
 ...

so oI (space groups 23=I222 or 24=I212121) or the two mC (space group 5=C2) are possibilities for indexing, and of course P1. Integration in P1 (because of SPACE_GROUP_NUMBER=0 in XDS.INP) results in the following table for space group determination in CORRECT:

 SPACE-GROUP         UNIT CELL CONSTANTS            UNIQUE   Rmeas  COMPARED  LATTICE-
   NUMBER      a      b      c   alpha beta gamma                            CHARACTER

       1      74.1   78.6  124.0  71.8  74.8  90.4    6959    22.5     5309    31 aP
   *  23      74.1   78.6  226.6  90.0  90.0  90.0    2735    39.5     9533    42 oI
       5     235.7   78.6   74.1  90.0 106.1  90.0    3922    31.0     8346    41 mC
       5     239.6   74.1   78.6  90.0 109.0  90.0    5111    30.7     7157    37 mC
       1      74.1   78.6  124.0 108.2 105.2  90.4    6959    22.5     5309    44 aP

The automatic choice gave 23 as a result. This is because the associated Rmeas (39.5) is lower than MAX_FAC_RMEAS * (lowest Rmeas) = 2 * 22.5 = 45.0. However, the C2 values of 30.7 and 31.0 are significantly lower still, and the question needs further investigation.

checking the CORRECT assignment with pointless

pointless XDS_ASCII.HKL gives:

Analysing rotational symmetry in lattice group I 4/m m m
----------------------------------------------

<!--SUMMARY_BEGIN-->

Scores for each symmetry element

Nelmt  Lklhd  Z-cc    CC        N  Rmeas    Symmetry & operator (in Lattice Cell)

  1   0.856   7.77   0.78    9368  0.224     identity
  2   0.139   2.98   0.30    6376  0.894     2-fold l ( 0 0 1) {-h,-k,l}
  3   0.842   8.02   0.80   18679  0.234 **  2-fold k ( 0 1 0) {-h,k,-l}
  4   0.148   3.10   0.31    5858  1.254     2-fold h ( 1 0 0) {h,-k,-l}
  5   0.073   1.25   0.13   12111  1.077     2-fold   ( 1-1 0) {-k,-h,-l}
  6   0.071   1.11   0.11   12293  1.152     2-fold   ( 1 1 0) {k,h,-l}
  7   0.068   0.83   0.08   24758  1.084     4-fold l ( 0 0 1) {-k,h,l}{k,-h,l}

and this shows that actually there is only one instead of three two-fold axes, despite the fact that CORRECT auto-chose the orthorhombic system and possibly even rejected some reflections that do not fit it well. Pointless then re-indexes to I2 and suggests:

Best Solution:    space group I 1 2 1

   Reindex operator:                   [h,k,l]                 
   Laue group probability:             0.763
   Systematic absence probability:     1.000
   Total probability:                  0.763
   Space group confidence:             0.687
   Laue group confidence               0.687

   Unit cell:   78.05  80.78 235.63     90.00  90.00  90.00

   50.67 to   3.73   - Resolution range used for Laue group search

   50.67 to   3.08   - Resolution range in file, used for systematic absence check

   Number of batches in file:    120

The data do not appear to be twinned, from the L-test

$$ <!--SUMMARY_END-->


HKLIN spacegroup: I 2 2 2  body-centred orthorhombic

$TEXT:Warning:$$ $$

The input crystal system is body-centred orthorhombic
 (Cell:   78.05  80.78 235.63     90.00  90.00  90.00)
The crystal system chosen for output is body-centred monoclinic
 (Cell:   78.05  80.78 235.63     90.00  90.00  90.00)

$TEXT:Warning:$$ $$
WARNING: 
WARNING:
The chosen output crystal system is different from that used for integration of the input file(s).
You should rerun the integration in the chosen crystal system because the cell constraints differ
$$

Filename: 

^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^


Final point group choice has alternative indexing possibilities

Alternative indexing possibilities are marked '*' if the cells are 
  too different at the maximum resolution

    CellDifference(A) ReindexOperator
  1      0.0          [h,k,l]
  2      0.0          [h,-k,-l]
  3      8.0 *        [k,-h,l]
  4      8.0 *        [-k,h,l]

At the bottom of the output, we see that other indexing possibilities exist. That means that one has to be very careful when merging crystals from this project, and that there may also be the possibility of twinning.

In this particular case, CORRECT chose the wrong symmetry, whereas pointless identified the correct symmetry elements. I have also seen cases where pointless mis-identified the symmetry, usually on the side of too high symmetry. To avoid mistakes in space group identification, it is absolutely crucial to read and understand the tables that the programs print.

a more sensible way to run pointless

pointless should really be run with the "SETTING SYMMETRY-BASED" option. When doing that, the output changes to

Best Solution:    space group C 1 2 1

   Reindex operator:                  [h+l,k,-h]               
   Laue group probability:             0.807
   Systematic absence probability:     1.000
   Total probability:                  0.807
   Space group confidence:             0.734
   Laue group confidence               0.734

   Unit cell:  248.53  80.86  78.08     90.00 108.31  90.00

   40.76 to   3.80   - Resolution range used for Laue group search

   40.76 to   3.08   - Resolution range in file, used for systematic absence check

   Number of batches in file:    120

The data do not appear to be twinned, from the L-test

$$ <!--SUMMARY_END-->


HKLIN spacegroup: I 2 2 2  body-centred orthorhombic

$TEXT:Warning:$$ $$

The input crystal system is body-centred orthorhombic
 (Cell:   78.08  80.86 235.95     90.00  90.00  90.00)
The crystal system chosen for output is C-centred monoclinic
 (Cell:  248.53  80.86  78.08     90.00 108.31  90.00)

$TEXT:Warning:$$ $$
WARNING: 
WARNING:
The chosen output crystal system is different from that used for integration of the input file(s).
You should rerun the integration in the chosen crystal system because the cell constraints differ
$$

so the spacegroup given is the more normal C2 setting (instead of A2 or I2). Unfortunately, pointless does not seem to print out the table of "alternative indexing possibilities" in this mode - but possibly the table is only printed in the I2 case because the beta angle comes out as 90.0°.

not biasing the cell parameters, and avoiding premature outlier rejection

CORRECT can easily be forced not to assign a spacegroup, and consequently will not reject outliers based on a too high symmetry assignment. To this end one simply supplies space group P1 and its unit cell:

SPACE_GROUP_NUMBER=1 
UNIT_CELL_CONSTANTS= 74.1   78.6  124.0 108.2 105.2  90.4

in XDS.INP and re-runs CORRECT. That gives an unbiased XDS_ASCII.HKL, with no angles set to 90°. pointless with SETTING SYMMETRY_BASED then gives

Best Solution:    space group C 1 2 1

   Reindex operator:                [-k-2l,-k,-h]              
   Laue group probability:             0.849
   Systematic absence probability:     1.000
   Total probability:                  0.849
   Space group confidence:             0.770
   Laue group confidence               0.770

   Unit cell:  233.70  78.42  73.22     90.31 105.34  89.77

and without SETTING SYMMETRY_BASED

Best Solution:    space group I 1 2 1

   Reindex operator:                [-h,-k,h+k+2l]             
   Laue group probability:             0.838
   Systematic absence probability:     1.000
   Total probability:                  0.838
   Space group confidence:             0.753
   Laue group confidence               0.753

   Unit cell:  233.70  78.42  73.22     90.31 105.34  89.77

the dreadful I2 space group nomenclature (and I have no idea why the probability and confidence values are worse than in C2). But anyway this shows that there are two non-equivalent ways to index the same lattice!

final steps

Finally, XDS (but only JOB=DEFPIX INTEGRATE CORRECT) should be re-run with

SPACE_GROUP_NUMBER=5 
UNIT_CELL_CONSTANTS= 233.70  78.42  73.22     90 105.34  90

because this enforces just the correct cell constraints.

See also

The 230 3-Dimensional Space Groups