Analogues of Sialic Acids as Potential Sialidase Inhibitors. Synthesis of C 6 and C 7 Analogues of N ‐Acetyl‐6‐amino‐2,6‐dideoxyneuraminic Acid
The piperidines 12 – 18 , piperidmose analogues of Neu5Ac ( 1 ) with a shortened side chain, were synthesized from N ‐acetyl‐ D ‐glucosamine via the azidoalkene 32 and tested as inhibitors of Vibrio cholerae sialidase. Deoxygenation at C(4) of the uronate 22 , obtained from the known D ‐GlcNAc deriv...
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| creator | Glänzer, Brigitte I. Györgydeák, Zoltan Bernet, Bruno Vasella, Andrea |
| description | The piperidines
12
–
18
, piperidmose analogues of Neu5Ac (
1
) with a shortened side chain, were synthesized from
N
‐acetyl‐
D
‐glucosamine
via
the azidoalkene
32
and tested as inhibitors of
Vibrio cholerae
sialidase. Deoxygenation at C(4) of the uronate
22
, obtained from the known
D
‐GlcNAc derivative
20
, was effected by β‐elimination (→
23
), exchange of the AcO at C(3) with a (
t
‐Bu)Me
2
SiO group and hydrogenation (→
26
;
Scheme 1
). Chain extension of
26
by reaction with Me
3
SiCH
2
MgCl gave the
D
‐
ido
‐dihydroxysilane
28
, which was transformed into the unsaturated
L
‐
xylo
‐mesylate
29
and further into the
L
‐
lyxo
‐alcohol
30
, the mesylate
31
, and the
L
‐
xylo
‐azide
32
. The derivatives
29
–
31
prefer a sickle zig‐zag and
32
mainly an extended zig‐zag conformation (
Fig. 2
). The piperidinecarboxylate
15
was obtained from
32
by ozonolysis (→
33
), intramolecular reductive animation (→
34
), and deprotection, while reductive animation of
34
with glycolaldehyde (→
35
) and deprotection gave
16
(
Scheme 2
). An intramolecular azide‐olefin cycloaddition of
32
yielded exclusively the fused dihydrotriazole
36
, while the lactone
39
did not cyclize (
Scheme 3
). Treatment of
36
with AcOH (→
37
) followed by hydrolysis (→
38
) and deprotection led to the amino acid
18
. To prepare the (hydroxymethyl)piperidinecarboxylates
12
and
17
,
32
was first dihydroxylated (
Scheme 4
). The
L
‐
gluco
‐diol
40
was obtained as the major product, in agreement with
Kishi's
rule. Silylation of
40
(→
42
), oxidation with periodinane (→
44
), and reductive animation gave the
L
‐
gluco
‐piperidine
45
. It was, on the one hand, deprotected to the amino acid
12
and, on the other hand,
N
‐phenylated (→
46
) and deprotected to
17
. While
45
and
12
adopt a
2
C
5
conformation, the analogous
N
‐Ph derivatives
46
and
17
adopt a
5
C
2
and a
B
3,6
conformation, respectively, on account of the allylic 1,3‐strain. The conformational effects of this 1,3‐strain are also evident in the carbamate
47
, obtained from
45
(
Scheme 5
), and in the C(2)‐epimerized bicyclic ether
48
, which was formed upon treatment of
47
with (diethylamino)sulfur trifluoride (DAST). Fluorination of
40
with DAST (→
49
) followed by treatment with AcOH led to the
D
‐
ido
‐fluorohydrin
50
. Oxidation of
50
(→
51
) followed by a
Staudinger
reaction and reduction with NaBH
3
CN afforded the (fluoromethyl)piperidine
52
, while reductive amination of
51
with H
2
/Pd led to the methylpiperidine
55
, which was sim |
| doi_str_mv | 10.1002/hlca.19910740214 |
| format | Article |
| fullrecord | <record><control><sourceid>crossref</sourceid><recordid>TN_cdi_crossref_primary_10_1002_hlca_19910740214</recordid><sourceformat>XML</sourceformat><sourcesystem>PC</sourcesystem><sourcerecordid>10_1002_hlca_19910740214</sourcerecordid><originalsourceid>FETCH-LOGICAL-c884-c8bc8e67a84537e67c0bdeb0bb4a4aa196713e8ffe6d34d3d005f9f7e61c0f913</originalsourceid><addsrcrecordid>eNpVUMtOwzAQtBBIlMKdoz-AlHXixPExqnhUqgCpPXCLHD-oUWqjOJXIjU_gyu_xJTi0BzjszuxrtBqELgnMCEB6vWmlmBHOCTAKKaFHaELyNE3SguXHaAJAygQIfz5FZyG8AgDnwCboq3Ki9S87HbA3eGVFayWupFUBi4CffK9dH5v7iRJB44Xb2Mb2vgszvBpcv9HB_h7PcYGFUxEZ_qf6gL8_Piup-6GNpIghttb5iOnVWCmrtH8fnN514-DwwDk6MaIN-uKAU7S-vVnP75Pl491iXi0TWZY0pkaWumCipHnGIpHQKN1A01BBhSC8YCTTpTG6UBlVmQLIDTdxk0gwnGRTBHtZ2fkQOm3qt85uRTfUBOrR2Xp0tv7jbPYD1yZykQ</addsrcrecordid><sourcetype>Aggregation Database</sourcetype><iscdi>true</iscdi><recordtype>article</recordtype></control><display><type>article</type><title>Analogues of Sialic Acids as Potential Sialidase Inhibitors. Synthesis of C 6 and C 7 Analogues of N ‐Acetyl‐6‐amino‐2,6‐dideoxyneuraminic Acid</title><source>Wiley Online Library Journals</source><creator>Glänzer, Brigitte I. ; Györgydeák, Zoltan ; Bernet, Bruno ; Vasella, Andrea</creator><creatorcontrib>Glänzer, Brigitte I. ; Györgydeák, Zoltan ; Bernet, Bruno ; Vasella, Andrea</creatorcontrib><description>The piperidines
12
–
18
, piperidmose analogues of Neu5Ac (
1
) with a shortened side chain, were synthesized from
N
‐acetyl‐
D
‐glucosamine
via
the azidoalkene
32
and tested as inhibitors of
Vibrio cholerae
sialidase. Deoxygenation at C(4) of the uronate
22
, obtained from the known
D
‐GlcNAc derivative
20
, was effected by β‐elimination (→
23
), exchange of the AcO at C(3) with a (
t
‐Bu)Me
2
SiO group and hydrogenation (→
26
;
Scheme 1
). Chain extension of
26
by reaction with Me
3
SiCH
2
MgCl gave the
D
‐
ido
‐dihydroxysilane
28
, which was transformed into the unsaturated
L
‐
xylo
‐mesylate
29
and further into the
L
‐
lyxo
‐alcohol
30
, the mesylate
31
, and the
L
‐
xylo
‐azide
32
. The derivatives
29
–
31
prefer a sickle zig‐zag and
32
mainly an extended zig‐zag conformation (
Fig. 2
). The piperidinecarboxylate
15
was obtained from
32
by ozonolysis (→
33
), intramolecular reductive animation (→
34
), and deprotection, while reductive animation of
34
with glycolaldehyde (→
35
) and deprotection gave
16
(
Scheme 2
). An intramolecular azide‐olefin cycloaddition of
32
yielded exclusively the fused dihydrotriazole
36
, while the lactone
39
did not cyclize (
Scheme 3
). Treatment of
36
with AcOH (→
37
) followed by hydrolysis (→
38
) and deprotection led to the amino acid
18
. To prepare the (hydroxymethyl)piperidinecarboxylates
12
and
17
,
32
was first dihydroxylated (
Scheme 4
). The
L
‐
gluco
‐diol
40
was obtained as the major product, in agreement with
Kishi's
rule. Silylation of
40
(→
42
), oxidation with periodinane (→
44
), and reductive animation gave the
L
‐
gluco
‐piperidine
45
. It was, on the one hand, deprotected to the amino acid
12
and, on the other hand,
N
‐phenylated (→
46
) and deprotected to
17
. While
45
and
12
adopt a
2
C
5
conformation, the analogous
N
‐Ph derivatives
46
and
17
adopt a
5
C
2
and a
B
3,6
conformation, respectively, on account of the allylic 1,3‐strain. The conformational effects of this 1,3‐strain are also evident in the carbamate
47
, obtained from
45
(
Scheme 5
), and in the C(2)‐epimerized bicyclic ether
48
, which was formed upon treatment of
47
with (diethylamino)sulfur trifluoride (DAST). Fluorination of
40
with DAST (→
49
) followed by treatment with AcOH led to the
D
‐
ido
‐fluorohydrin
50
. Oxidation of
50
(→
51
) followed by a
Staudinger
reaction and reduction with NaBH
3
CN afforded the (fluoromethyl)piperidine
52
, while reductive amination of
51
with H
2
/Pd led to the methylpiperidine
55
, which was similarly obtained from the keto tosylate
54
and from the dihydrotriazole
36
. Deprotection of
52
and
55
gave the amino acids
13
and
14
, respectively. The aniline
17
does not inhibit
V. cholerae
sialidase; the piperidines
12
–
16
and
18
are weak inhibitors, evidencing the importance of an intact 1,2,3‐trihydroxypropyl side chain.</description><identifier>ISSN: 0018-019X</identifier><identifier>EISSN: 1522-2675</identifier><identifier>DOI: 10.1002/hlca.19910740214</identifier><language>eng</language><ispartof>Helvetica chimica acta, 1991-03, Vol.74 (2), p.343-369</ispartof><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>false</woscitedreferencessubscribed><citedby>FETCH-LOGICAL-c884-c8bc8e67a84537e67c0bdeb0bb4a4aa196713e8ffe6d34d3d005f9f7e61c0f913</citedby><cites>FETCH-LOGICAL-c884-c8bc8e67a84537e67c0bdeb0bb4a4aa196713e8ffe6d34d3d005f9f7e61c0f913</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27923,27924</link.rule.ids></links><search><creatorcontrib>Glänzer, Brigitte I.</creatorcontrib><creatorcontrib>Györgydeák, Zoltan</creatorcontrib><creatorcontrib>Bernet, Bruno</creatorcontrib><creatorcontrib>Vasella, Andrea</creatorcontrib><title>Analogues of Sialic Acids as Potential Sialidase Inhibitors. Synthesis of C 6 and C 7 Analogues of N ‐Acetyl‐6‐amino‐2,6‐dideoxyneuraminic Acid</title><title>Helvetica chimica acta</title><description>The piperidines
12
–
18
, piperidmose analogues of Neu5Ac (
1
) with a shortened side chain, were synthesized from
N
‐acetyl‐
D
‐glucosamine
via
the azidoalkene
32
and tested as inhibitors of
Vibrio cholerae
sialidase. Deoxygenation at C(4) of the uronate
22
, obtained from the known
D
‐GlcNAc derivative
20
, was effected by β‐elimination (→
23
), exchange of the AcO at C(3) with a (
t
‐Bu)Me
2
SiO group and hydrogenation (→
26
;
Scheme 1
). Chain extension of
26
by reaction with Me
3
SiCH
2
MgCl gave the
D
‐
ido
‐dihydroxysilane
28
, which was transformed into the unsaturated
L
‐
xylo
‐mesylate
29
and further into the
L
‐
lyxo
‐alcohol
30
, the mesylate
31
, and the
L
‐
xylo
‐azide
32
. The derivatives
29
–
31
prefer a sickle zig‐zag and
32
mainly an extended zig‐zag conformation (
Fig. 2
). The piperidinecarboxylate
15
was obtained from
32
by ozonolysis (→
33
), intramolecular reductive animation (→
34
), and deprotection, while reductive animation of
34
with glycolaldehyde (→
35
) and deprotection gave
16
(
Scheme 2
). An intramolecular azide‐olefin cycloaddition of
32
yielded exclusively the fused dihydrotriazole
36
, while the lactone
39
did not cyclize (
Scheme 3
). Treatment of
36
with AcOH (→
37
) followed by hydrolysis (→
38
) and deprotection led to the amino acid
18
. To prepare the (hydroxymethyl)piperidinecarboxylates
12
and
17
,
32
was first dihydroxylated (
Scheme 4
). The
L
‐
gluco
‐diol
40
was obtained as the major product, in agreement with
Kishi's
rule. Silylation of
40
(→
42
), oxidation with periodinane (→
44
), and reductive animation gave the
L
‐
gluco
‐piperidine
45
. It was, on the one hand, deprotected to the amino acid
12
and, on the other hand,
N
‐phenylated (→
46
) and deprotected to
17
. While
45
and
12
adopt a
2
C
5
conformation, the analogous
N
‐Ph derivatives
46
and
17
adopt a
5
C
2
and a
B
3,6
conformation, respectively, on account of the allylic 1,3‐strain. The conformational effects of this 1,3‐strain are also evident in the carbamate
47
, obtained from
45
(
Scheme 5
), and in the C(2)‐epimerized bicyclic ether
48
, which was formed upon treatment of
47
with (diethylamino)sulfur trifluoride (DAST). Fluorination of
40
with DAST (→
49
) followed by treatment with AcOH led to the
D
‐
ido
‐fluorohydrin
50
. Oxidation of
50
(→
51
) followed by a
Staudinger
reaction and reduction with NaBH
3
CN afforded the (fluoromethyl)piperidine
52
, while reductive amination of
51
with H
2
/Pd led to the methylpiperidine
55
, which was similarly obtained from the keto tosylate
54
and from the dihydrotriazole
36
. Deprotection of
52
and
55
gave the amino acids
13
and
14
, respectively. The aniline
17
does not inhibit
V. cholerae
sialidase; the piperidines
12
–
16
and
18
are weak inhibitors, evidencing the importance of an intact 1,2,3‐trihydroxypropyl side chain.</description><issn>0018-019X</issn><issn>1522-2675</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1991</creationdate><recordtype>article</recordtype><recordid>eNpVUMtOwzAQtBBIlMKdoz-AlHXixPExqnhUqgCpPXCLHD-oUWqjOJXIjU_gyu_xJTi0BzjszuxrtBqELgnMCEB6vWmlmBHOCTAKKaFHaELyNE3SguXHaAJAygQIfz5FZyG8AgDnwCboq3Ki9S87HbA3eGVFayWupFUBi4CffK9dH5v7iRJB44Xb2Mb2vgszvBpcv9HB_h7PcYGFUxEZ_qf6gL8_Piup-6GNpIghttb5iOnVWCmrtH8fnN514-DwwDk6MaIN-uKAU7S-vVnP75Pl491iXi0TWZY0pkaWumCipHnGIpHQKN1A01BBhSC8YCTTpTG6UBlVmQLIDTdxk0gwnGRTBHtZ2fkQOm3qt85uRTfUBOrR2Xp0tv7jbPYD1yZykQ</recordid><startdate>19910313</startdate><enddate>19910313</enddate><creator>Glänzer, Brigitte I.</creator><creator>Györgydeák, Zoltan</creator><creator>Bernet, Bruno</creator><creator>Vasella, Andrea</creator><scope>AAYXX</scope><scope>CITATION</scope></search><sort><creationdate>19910313</creationdate><title>Analogues of Sialic Acids as Potential Sialidase Inhibitors. Synthesis of C 6 and C 7 Analogues of N ‐Acetyl‐6‐amino‐2,6‐dideoxyneuraminic Acid</title><author>Glänzer, Brigitte I. ; Györgydeák, Zoltan ; Bernet, Bruno ; Vasella, Andrea</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c884-c8bc8e67a84537e67c0bdeb0bb4a4aa196713e8ffe6d34d3d005f9f7e61c0f913</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>1991</creationdate><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Glänzer, Brigitte I.</creatorcontrib><creatorcontrib>Györgydeák, Zoltan</creatorcontrib><creatorcontrib>Bernet, Bruno</creatorcontrib><creatorcontrib>Vasella, Andrea</creatorcontrib><collection>CrossRef</collection><jtitle>Helvetica chimica acta</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Glänzer, Brigitte I.</au><au>Györgydeák, Zoltan</au><au>Bernet, Bruno</au><au>Vasella, Andrea</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Analogues of Sialic Acids as Potential Sialidase Inhibitors. Synthesis of C 6 and C 7 Analogues of N ‐Acetyl‐6‐amino‐2,6‐dideoxyneuraminic Acid</atitle><jtitle>Helvetica chimica acta</jtitle><date>1991-03-13</date><risdate>1991</risdate><volume>74</volume><issue>2</issue><spage>343</spage><epage>369</epage><pages>343-369</pages><issn>0018-019X</issn><eissn>1522-2675</eissn><abstract>The piperidines
12
–
18
, piperidmose analogues of Neu5Ac (
1
) with a shortened side chain, were synthesized from
N
‐acetyl‐
D
‐glucosamine
via
the azidoalkene
32
and tested as inhibitors of
Vibrio cholerae
sialidase. Deoxygenation at C(4) of the uronate
22
, obtained from the known
D
‐GlcNAc derivative
20
, was effected by β‐elimination (→
23
), exchange of the AcO at C(3) with a (
t
‐Bu)Me
2
SiO group and hydrogenation (→
26
;
Scheme 1
). Chain extension of
26
by reaction with Me
3
SiCH
2
MgCl gave the
D
‐
ido
‐dihydroxysilane
28
, which was transformed into the unsaturated
L
‐
xylo
‐mesylate
29
and further into the
L
‐
lyxo
‐alcohol
30
, the mesylate
31
, and the
L
‐
xylo
‐azide
32
. The derivatives
29
–
31
prefer a sickle zig‐zag and
32
mainly an extended zig‐zag conformation (
Fig. 2
). The piperidinecarboxylate
15
was obtained from
32
by ozonolysis (→
33
), intramolecular reductive animation (→
34
), and deprotection, while reductive animation of
34
with glycolaldehyde (→
35
) and deprotection gave
16
(
Scheme 2
). An intramolecular azide‐olefin cycloaddition of
32
yielded exclusively the fused dihydrotriazole
36
, while the lactone
39
did not cyclize (
Scheme 3
). Treatment of
36
with AcOH (→
37
) followed by hydrolysis (→
38
) and deprotection led to the amino acid
18
. To prepare the (hydroxymethyl)piperidinecarboxylates
12
and
17
,
32
was first dihydroxylated (
Scheme 4
). The
L
‐
gluco
‐diol
40
was obtained as the major product, in agreement with
Kishi's
rule. Silylation of
40
(→
42
), oxidation with periodinane (→
44
), and reductive animation gave the
L
‐
gluco
‐piperidine
45
. It was, on the one hand, deprotected to the amino acid
12
and, on the other hand,
N
‐phenylated (→
46
) and deprotected to
17
. While
45
and
12
adopt a
2
C
5
conformation, the analogous
N
‐Ph derivatives
46
and
17
adopt a
5
C
2
and a
B
3,6
conformation, respectively, on account of the allylic 1,3‐strain. The conformational effects of this 1,3‐strain are also evident in the carbamate
47
, obtained from
45
(
Scheme 5
), and in the C(2)‐epimerized bicyclic ether
48
, which was formed upon treatment of
47
with (diethylamino)sulfur trifluoride (DAST). Fluorination of
40
with DAST (→
49
) followed by treatment with AcOH led to the
D
‐
ido
‐fluorohydrin
50
. Oxidation of
50
(→
51
) followed by a
Staudinger
reaction and reduction with NaBH
3
CN afforded the (fluoromethyl)piperidine
52
, while reductive amination of
51
with H
2
/Pd led to the methylpiperidine
55
, which was similarly obtained from the keto tosylate
54
and from the dihydrotriazole
36
. Deprotection of
52
and
55
gave the amino acids
13
and
14
, respectively. The aniline
17
does not inhibit
V. cholerae
sialidase; the piperidines
12
–
16
and
18
are weak inhibitors, evidencing the importance of an intact 1,2,3‐trihydroxypropyl side chain.</abstract><doi>10.1002/hlca.19910740214</doi><tpages>27</tpages></addata></record> |
| fulltext | fulltext |
| identifier | ISSN: 0018-019X |
| ispartof | Helvetica chimica acta, 1991-03, Vol.74 (2), p.343-369 |
| issn | 0018-019X 1522-2675 |
| language | eng |
| recordid | cdi_crossref_primary_10_1002_hlca_19910740214 |
| source | Wiley Online Library Journals |
| title | Analogues of Sialic Acids as Potential Sialidase Inhibitors. Synthesis of C 6 and C 7 Analogues of N ‐Acetyl‐6‐amino‐2,6‐dideoxyneuraminic Acid |
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